This document contains the specifications and commands for simulating the capacitance of a MOSFET device using numerical device simulation software. It defines the mesh, regions, electrodes, doping, contacts, material properties, and models used in the simulation. It then commands the software to solve the device equations for different applied biases and output plots of the potential and other quantities along the device cross-section.
This document describes a device simulation of the capacitance of a MOSFET. It specifies the mesh, regions, electrodes, doping, contacts, and materials of the simulated MOSFET structure. It then performs simulations by solving for the initial conditions and applying a range of biases to the gate electrode to determine the potential distribution and output potential profiles to files.
This document describes a device simulation of a MOSFET capacitor. It specifies the mesh, regions, electrodes, doping, contacts, and materials of the simulation. It then solves for the initial conditions and applied bias over a range of voltages, plotting the potential and other quantities at each step. The goal is to simulate the MOSFET capacitor and analyze its behavior under varying voltages.
1. The document provides 135 integrals to solve. It gives the integral expressions without showing the solutions.
2. The integrals involve a variety of functions, such as trigonometric functions, logarithmic functions, and exponential functions.
3. The limits of integration range from 0 to π, −π to π, or other values, depending on the specific integral.
Flame was one of the most complex cyber threats ever discovered. It used sophisticated techniques like man-in-the-middle attacks and intercepting Windows Update to infect systems. The attackers were able to forge digital certificates due to a weakness in the MD5 hash function, allowing them to disguise malware as legitimate Microsoft software updates. This presentation discusses Flame's technical capabilities and the challenges it posed for security professionals working to understand and mitigate the threat.
This document discusses Python loops and conditionals. It provides examples of using break and continue in for loops. It also covers operators like == and !=, calculating remainders with the % operator, using range() to iterate over a range of numbers, appending to lists, taking user input, nested loops, and arithmetic operations.
The document contains code for plotting various implicit and parametric 3D surfaces in Maple. It includes implicit plots of spheres, ellipsoids, hyperboloids, cylinders, cones and other quadric surfaces defined by implicit equations. It also contains parametric plots describing surfaces like helices, cylinders, tori and surfaces of revolution generated by rotating curves around axes. All plots are generated over the domain -5 to 5 for variables x, y and z with varying numbers of sample points.
This document describes a device simulation of the capacitance of a MOSFET. It specifies the mesh, regions, electrodes, doping, contacts, and materials of the simulated MOSFET structure. It then performs simulations by solving for the initial conditions and applying a range of biases to the gate electrode to determine the potential distribution and output potential profiles to files.
This document describes a device simulation of a MOSFET capacitor. It specifies the mesh, regions, electrodes, doping, contacts, and materials of the simulation. It then solves for the initial conditions and applied bias over a range of voltages, plotting the potential and other quantities at each step. The goal is to simulate the MOSFET capacitor and analyze its behavior under varying voltages.
1. The document provides 135 integrals to solve. It gives the integral expressions without showing the solutions.
2. The integrals involve a variety of functions, such as trigonometric functions, logarithmic functions, and exponential functions.
3. The limits of integration range from 0 to π, −π to π, or other values, depending on the specific integral.
Flame was one of the most complex cyber threats ever discovered. It used sophisticated techniques like man-in-the-middle attacks and intercepting Windows Update to infect systems. The attackers were able to forge digital certificates due to a weakness in the MD5 hash function, allowing them to disguise malware as legitimate Microsoft software updates. This presentation discusses Flame's technical capabilities and the challenges it posed for security professionals working to understand and mitigate the threat.
This document discusses Python loops and conditionals. It provides examples of using break and continue in for loops. It also covers operators like == and !=, calculating remainders with the % operator, using range() to iterate over a range of numbers, appending to lists, taking user input, nested loops, and arithmetic operations.
The document contains code for plotting various implicit and parametric 3D surfaces in Maple. It includes implicit plots of spheres, ellipsoids, hyperboloids, cylinders, cones and other quadric surfaces defined by implicit equations. It also contains parametric plots describing surfaces like helices, cylinders, tori and surfaces of revolution generated by rotating curves around axes. All plots are generated over the domain -5 to 5 for variables x, y and z with varying numbers of sample points.
The document describes a simulation of an NMOS transistor. It defines the mesh, regions, doping concentrations, materials, and electrical contacts. Initial results are plotted including potential, electric field, and carrier concentrations to analyze the transistor behavior. The gate voltage is then swept to model transistor operation and output current-voltage characteristics.
The document describes a simulation of an NMOS transistor. It defines the mesh, regions, doping concentrations, materials, and electrical contacts. It then performs the simulation, solving the device at different biases and extracting output parameters and plots.
This document provides the solutions manual for Trigonometry 10th Edition by Larson. It includes solutions for all exercises in Chapter 2 on Analytic Trigonometry. The chapter covers fundamental trigonometric identities, verifying identities, solving trigonometric equations, sum and difference formulas, and multiple-angle and product-to-sum formulas. The solutions provide step-by-step workings to arrive at the answers for each problem.
This document provides the solutions manual for Trigonometry 10th Edition by Larson. It includes solutions for all exercises in Chapter 2 on Analytic Trigonometry. The chapter covers fundamental trigonometric identities, verifying identities, solving trigonometric equations, sum and difference formulas, and multiple-angle and product-to-sum formulas. The solutions provide step-by-step workings to arrive at the answers for each problem.
Solutions manual for fundamentals of business math canadian 3rd edition by je...Pollockker
This document provides the solutions manual for the 3rd Canadian edition of the textbook "Fundamentals of Business Math" by Jerome. It contains solutions to exercises in Chapter 2 on reviewing and applying algebra. The exercises cover basic, intermediate, and advanced algebra problems involving operations with variables, exponents, percentages, and compound interest.
We will discuss the following: Artificial Neural Network, Perceptron Learning Example, Artificial Neural Network Training Process, Forward propagation, Backpropagation, Classification of Handwritten Digits, Neural Network Zoo.
This document contains sample problems and solutions from a mechanical engineering design textbook. Problem 1-5 involves calculating the optimal speed and throughput of vehicles on a road for different lane lengths. Problem 1-6 introduces the concept of a figure of merit and calculates the optimal angle that maximizes this metric. Subsequent problems involve calculating various mechanical properties and conversions between units.
Integration is a reverse process of differentiation. The integral or primitive of a function f(x) with
respect to x is that function (x) whose derivative with respect to x is the given function f(x). It is
i. 0. dx = c
ii. 1.dx = x + c
iii. k.dx = kx + c (k R)
xn1
expressed symbolically as -
zf (x) dx (x)
iv. xn dx =
n 1
+ c (n –1)
v. z1 dx = log
x + c
Thus x e
vi. ex dx = ex + c
ax
The process of finding the integral of a function is called Integration and the given function is
vii. ax dx =
loge
a + c = ax loga e + c
called Integrand. Now, it is obvious that the operation of integration is inverse operation of differentiation. Hence integral of a function is also named as anti-derivative of that function.
Further we observe that-
viii. sin x dx = – cos x + c
ix. cos x dx = sin x + c
x. tan x dx = log sec x + c = – log cos x + c
d (x2 )
dx
2 x
xi. cot x dx = log sin x + c
d (x2 2) 2xV| 2xdx x2 constant
xii. sec x dx = log(secx + tanx) + c
dx = – log (sec x –tan x) + c
d 2
dx (x k) 2x|
= log tan
FGH xIJ+ c
So we always add a constant to the integral of function, which is called the constant of
xiii. cosec x dx = – log (cosec x + cot x) + c
Integration. It is generally denoted by c. Due to presence of this constant such an integral is called an Indefinite integral.
= log (cosec x – cot x) + c = log tan
xiv. sec x tan x dx = sec x + c
FGHxIJK+ c
If f(x), g(x) are two functions of a variable x and k is a constant, then-
(i) k f(x) dx = k f(x) dx.
(ii) [f(x) g(x)] dx = f(x)dx ± g(x) dx
(iii) d/dx ( f(x) dx) = f(x)
(iv) f(x)KJdx = f(x)
The following integrals are directly obtained from the derivatives of standard functions.
xv. cosec x cot x dx = – cosec x + c
xvi. sec2 x dx = tan x + c
xvii. cosec2 x dx = – cot x + c xviii. sinh x dx = cosh x + c
xix. cosh x dx = sinh x + c
xx. sech2 x dx = tanh x + c
xxi. cosech2 x dx = – coth x + c
xxii. sech x tanh x dx = – sech x + c
xxiii. cosech x coth x = – cosech x + c
1 1
FxI
eax
R 1FbI
xxiv. xxiv.
x2 + a2 dx =
a tan–1
GHa + c
= a2 b2
sin
STbx tan
GHaJK+ c
xxv. z 1
1
dx = log
FGx a + c
xxxv. zeax cos bx dx
x2 a2
2 a Hx aK
eax
xxvi. z 1
dx = 1 log FGa xIJ + c
= a2 b2
(a cos bx + b sin bx) + c
a2 x2
1
2 a Ha xK
FxI
= cos
STbx tan
1 b V+ c
xxvii. za2 x2 dx = sin–1
GHaJK+ c
FxI
Examples Integration of Function
xxviii. xxviii.
= – cos–1
1
dx = sinh–1
x2 a2
GHaJK+ c
FGxIJ+ c
Ex.1 Evaluate : zx–55 dx
Sol. x–55 dx
x54
= log (x +
) + c
= 54
+ c Ans.
xxix. z 1
dx = cosh–1
FGxIJ+ c
Ex.2 Evaluate :
zex2 1j2
x2 a2
= log (x +
HaK
) + c
Sol.
x
x4 2 x2 1
dx
x
xxx. xxx.
2 2 dx
= zx3 2x 1IJdx
za x
H xK
x4
= x +
2
a . sin–1
2
x + c
a
College algebra real mathematics real people 7th edition larson solutions manualJohnstonTBL
This document contains information about the College Algebra Real Mathematics Real People 7th Edition Larson textbook including:
- A link to download the solutions manual and test bank for the textbook
- An overview of the content covered in Chapter 2 on solving equations and inequalities, including linear equations, identities, conditionals, and more.
- 51 example problems from Chapter 2 with step-by-step solutions.
1. The document provides examples of constructing influence lines for statically determinate beams and trusses. It defines influence lines and shows how to determine the influence line for reactions, shear, and bending moment at various points.
2. Example problems are worked out step-by-step to show how to construct influence lines for a simple beam and a beam with a hinge support. The influence lines provide the response of the structure due to a moving unit load.
3. Equilibrium equations are also used to determine influence lines by relating reactions, shears and moments. General expressions for shear and moment are developed for a beam with multiple spans.
1. The document provides examples of constructing influence lines for statically determinate beams and trusses. It defines influence lines and shows how to determine the influence line for reactions, shear, and bending moment at various points.
2. Example problems are worked out step-by-step to show how to construct influence lines for a simple beam and a beam with a hinge support. The influence lines provide the response of the structure due to a moving unit load.
3. Equilibrium equations are also used to determine influence lines by relating reactions, shears and moments. General expressions for shear and bending moment over a beam with multiple spans are presented.
Hand book of Howard Anton calculus exercises 8th editionPriSim
The document contains the table of contents for a calculus textbook. It lists 17 chapters covering topics such as functions, limits, derivatives, integrals, vector calculus, and applications of calculus. It also includes 6 appendices reviewing concepts in real numbers, trigonometry, coordinate planes, and polynomial equations.
Update 22 models(Schottky Rectifier ) in SPICE PARK(APR2024)Tsuyoshi Horigome
This document provides an inventory update of 6,747 parts at Spice Park as of April 2024. It lists the part numbers, manufacturers, and quantities of various semiconductor components, including 1,697 Schottky rectifier diodes from 29 different manufacturers. It also includes details on passive components, batteries, mechanical parts, motors, and lamps in the inventory.
The document provides an inventory update from April 2024 of the Spice Park collection which contains 6,747 electronic components. It includes tables listing the types of semiconductor components, passive parts, batteries, mechanical parts, motors, and lamps in the collection along with their manufacturer and quantities. One of the semiconductor components, the general purpose rectifier diode, is broken down into a more detailed table with 116 entries providing part numbers, manufacturers, thermal ratings, and remarks.
Update 31 models(Diode/General ) in SPICE PARK(MAR2024)Tsuyoshi Horigome
The document provides an inventory update from March 2024 of parts in the Spice Park warehouse. It lists 6,725 total parts across various categories including semiconductors, passive parts, batteries, mechanical parts, motors, and lamps. The semiconductor section lists 652 general purpose rectifier diodes from 18 different manufacturers with quantities ranging from 2 to 145 pieces.
This document provides an inventory list of parts at Spice Park as of March 2024. It contains 3 sections - Semiconductor parts (diodes, transistors, ICs etc.), Passive parts (capacitors, resistors etc.), and Battery parts. For Semiconductor parts, it lists 36 different part types and provides the quantity of each part. It then provides further details of Diode/General Purpose Rectifiers, listing the manufacturer and quantity of 652 individual part numbers.
Update 29 models(Solar cell) in SPICE PARK(FEB2024)Tsuyoshi Horigome
The document provides an inventory update from February 2024 of Spice Park, which contains 6,694 total pieces of electronic components and parts. It lists 36 categories of semiconductor devices, 11 categories of passive parts, 10 types of batteries, 5 mechanical parts, DC motors, lamps, and power supplies. It provides the most detailed listing for solar cells, with 1,003 total pieces from 51 manufacturers listed with part numbers.
The document provides an inventory update from February 2024 of Spice Park, which contains 6,694 electronic components. It lists the components by type (e.g. semiconductor), part number, manufacturer, thermal rating, and quantity on hand. For example, it shows that there are 621 general purpose rectifier diodes from manufacturers such as Fairchild, Fuji, Intersil, Rohm, Shindengen, and Toshiba. The detailed four-page section provides further information on the first item, general purpose rectifier diodes, including 152 individual part numbers and specifications.
The document describes a simulation of an NMOS transistor. It defines the mesh, regions, doping concentrations, materials, and electrical contacts. Initial results are plotted including potential, electric field, and carrier concentrations to analyze the transistor behavior. The gate voltage is then swept to model transistor operation and output current-voltage characteristics.
The document describes a simulation of an NMOS transistor. It defines the mesh, regions, doping concentrations, materials, and electrical contacts. It then performs the simulation, solving the device at different biases and extracting output parameters and plots.
This document provides the solutions manual for Trigonometry 10th Edition by Larson. It includes solutions for all exercises in Chapter 2 on Analytic Trigonometry. The chapter covers fundamental trigonometric identities, verifying identities, solving trigonometric equations, sum and difference formulas, and multiple-angle and product-to-sum formulas. The solutions provide step-by-step workings to arrive at the answers for each problem.
This document provides the solutions manual for Trigonometry 10th Edition by Larson. It includes solutions for all exercises in Chapter 2 on Analytic Trigonometry. The chapter covers fundamental trigonometric identities, verifying identities, solving trigonometric equations, sum and difference formulas, and multiple-angle and product-to-sum formulas. The solutions provide step-by-step workings to arrive at the answers for each problem.
Solutions manual for fundamentals of business math canadian 3rd edition by je...Pollockker
This document provides the solutions manual for the 3rd Canadian edition of the textbook "Fundamentals of Business Math" by Jerome. It contains solutions to exercises in Chapter 2 on reviewing and applying algebra. The exercises cover basic, intermediate, and advanced algebra problems involving operations with variables, exponents, percentages, and compound interest.
We will discuss the following: Artificial Neural Network, Perceptron Learning Example, Artificial Neural Network Training Process, Forward propagation, Backpropagation, Classification of Handwritten Digits, Neural Network Zoo.
This document contains sample problems and solutions from a mechanical engineering design textbook. Problem 1-5 involves calculating the optimal speed and throughput of vehicles on a road for different lane lengths. Problem 1-6 introduces the concept of a figure of merit and calculates the optimal angle that maximizes this metric. Subsequent problems involve calculating various mechanical properties and conversions between units.
Integration is a reverse process of differentiation. The integral or primitive of a function f(x) with
respect to x is that function (x) whose derivative with respect to x is the given function f(x). It is
i. 0. dx = c
ii. 1.dx = x + c
iii. k.dx = kx + c (k R)
xn1
expressed symbolically as -
zf (x) dx (x)
iv. xn dx =
n 1
+ c (n –1)
v. z1 dx = log
x + c
Thus x e
vi. ex dx = ex + c
ax
The process of finding the integral of a function is called Integration and the given function is
vii. ax dx =
loge
a + c = ax loga e + c
called Integrand. Now, it is obvious that the operation of integration is inverse operation of differentiation. Hence integral of a function is also named as anti-derivative of that function.
Further we observe that-
viii. sin x dx = – cos x + c
ix. cos x dx = sin x + c
x. tan x dx = log sec x + c = – log cos x + c
d (x2 )
dx
2 x
xi. cot x dx = log sin x + c
d (x2 2) 2xV| 2xdx x2 constant
xii. sec x dx = log(secx + tanx) + c
dx = – log (sec x –tan x) + c
d 2
dx (x k) 2x|
= log tan
FGH xIJ+ c
So we always add a constant to the integral of function, which is called the constant of
xiii. cosec x dx = – log (cosec x + cot x) + c
Integration. It is generally denoted by c. Due to presence of this constant such an integral is called an Indefinite integral.
= log (cosec x – cot x) + c = log tan
xiv. sec x tan x dx = sec x + c
FGHxIJK+ c
If f(x), g(x) are two functions of a variable x and k is a constant, then-
(i) k f(x) dx = k f(x) dx.
(ii) [f(x) g(x)] dx = f(x)dx ± g(x) dx
(iii) d/dx ( f(x) dx) = f(x)
(iv) f(x)KJdx = f(x)
The following integrals are directly obtained from the derivatives of standard functions.
xv. cosec x cot x dx = – cosec x + c
xvi. sec2 x dx = tan x + c
xvii. cosec2 x dx = – cot x + c xviii. sinh x dx = cosh x + c
xix. cosh x dx = sinh x + c
xx. sech2 x dx = tanh x + c
xxi. cosech2 x dx = – coth x + c
xxii. sech x tanh x dx = – sech x + c
xxiii. cosech x coth x = – cosech x + c
1 1
FxI
eax
R 1FbI
xxiv. xxiv.
x2 + a2 dx =
a tan–1
GHa + c
= a2 b2
sin
STbx tan
GHaJK+ c
xxv. z 1
1
dx = log
FGx a + c
xxxv. zeax cos bx dx
x2 a2
2 a Hx aK
eax
xxvi. z 1
dx = 1 log FGa xIJ + c
= a2 b2
(a cos bx + b sin bx) + c
a2 x2
1
2 a Ha xK
FxI
= cos
STbx tan
1 b V+ c
xxvii. za2 x2 dx = sin–1
GHaJK+ c
FxI
Examples Integration of Function
xxviii. xxviii.
= – cos–1
1
dx = sinh–1
x2 a2
GHaJK+ c
FGxIJ+ c
Ex.1 Evaluate : zx–55 dx
Sol. x–55 dx
x54
= log (x +
) + c
= 54
+ c Ans.
xxix. z 1
dx = cosh–1
FGxIJ+ c
Ex.2 Evaluate :
zex2 1j2
x2 a2
= log (x +
HaK
) + c
Sol.
x
x4 2 x2 1
dx
x
xxx. xxx.
2 2 dx
= zx3 2x 1IJdx
za x
H xK
x4
= x +
2
a . sin–1
2
x + c
a
College algebra real mathematics real people 7th edition larson solutions manualJohnstonTBL
This document contains information about the College Algebra Real Mathematics Real People 7th Edition Larson textbook including:
- A link to download the solutions manual and test bank for the textbook
- An overview of the content covered in Chapter 2 on solving equations and inequalities, including linear equations, identities, conditionals, and more.
- 51 example problems from Chapter 2 with step-by-step solutions.
1. The document provides examples of constructing influence lines for statically determinate beams and trusses. It defines influence lines and shows how to determine the influence line for reactions, shear, and bending moment at various points.
2. Example problems are worked out step-by-step to show how to construct influence lines for a simple beam and a beam with a hinge support. The influence lines provide the response of the structure due to a moving unit load.
3. Equilibrium equations are also used to determine influence lines by relating reactions, shears and moments. General expressions for shear and moment are developed for a beam with multiple spans.
1. The document provides examples of constructing influence lines for statically determinate beams and trusses. It defines influence lines and shows how to determine the influence line for reactions, shear, and bending moment at various points.
2. Example problems are worked out step-by-step to show how to construct influence lines for a simple beam and a beam with a hinge support. The influence lines provide the response of the structure due to a moving unit load.
3. Equilibrium equations are also used to determine influence lines by relating reactions, shears and moments. General expressions for shear and bending moment over a beam with multiple spans are presented.
Hand book of Howard Anton calculus exercises 8th editionPriSim
The document contains the table of contents for a calculus textbook. It lists 17 chapters covering topics such as functions, limits, derivatives, integrals, vector calculus, and applications of calculus. It also includes 6 appendices reviewing concepts in real numbers, trigonometry, coordinate planes, and polynomial equations.
Update 22 models(Schottky Rectifier ) in SPICE PARK(APR2024)Tsuyoshi Horigome
This document provides an inventory update of 6,747 parts at Spice Park as of April 2024. It lists the part numbers, manufacturers, and quantities of various semiconductor components, including 1,697 Schottky rectifier diodes from 29 different manufacturers. It also includes details on passive components, batteries, mechanical parts, motors, and lamps in the inventory.
The document provides an inventory update from April 2024 of the Spice Park collection which contains 6,747 electronic components. It includes tables listing the types of semiconductor components, passive parts, batteries, mechanical parts, motors, and lamps in the collection along with their manufacturer and quantities. One of the semiconductor components, the general purpose rectifier diode, is broken down into a more detailed table with 116 entries providing part numbers, manufacturers, thermal ratings, and remarks.
Update 31 models(Diode/General ) in SPICE PARK(MAR2024)Tsuyoshi Horigome
The document provides an inventory update from March 2024 of parts in the Spice Park warehouse. It lists 6,725 total parts across various categories including semiconductors, passive parts, batteries, mechanical parts, motors, and lamps. The semiconductor section lists 652 general purpose rectifier diodes from 18 different manufacturers with quantities ranging from 2 to 145 pieces.
This document provides an inventory list of parts at Spice Park as of March 2024. It contains 3 sections - Semiconductor parts (diodes, transistors, ICs etc.), Passive parts (capacitors, resistors etc.), and Battery parts. For Semiconductor parts, it lists 36 different part types and provides the quantity of each part. It then provides further details of Diode/General Purpose Rectifiers, listing the manufacturer and quantity of 652 individual part numbers.
Update 29 models(Solar cell) in SPICE PARK(FEB2024)Tsuyoshi Horigome
The document provides an inventory update from February 2024 of Spice Park, which contains 6,694 total pieces of electronic components and parts. It lists 36 categories of semiconductor devices, 11 categories of passive parts, 10 types of batteries, 5 mechanical parts, DC motors, lamps, and power supplies. It provides the most detailed listing for solar cells, with 1,003 total pieces from 51 manufacturers listed with part numbers.
The document provides an inventory update from February 2024 of Spice Park, which contains 6,694 electronic components. It lists the components by type (e.g. semiconductor), part number, manufacturer, thermal rating, and quantity on hand. For example, it shows that there are 621 general purpose rectifier diodes from manufacturers such as Fairchild, Fuji, Intersil, Rohm, Shindengen, and Toshiba. The detailed four-page section provides further information on the first item, general purpose rectifier diodes, including 152 individual part numbers and specifications.
This document discusses circuit simulations using LTspice. It describes driving a circuit simulation by inserting a 250 ohm resistor between the output terminals. It also describes simulating a 1 channel bridge circuit where the DUT1 and DUT2 resistors are both set to 100 ohms and the input voltage is set to either 1V or 5V.
This document discusses parametric sweeps of external and internal resistance values Rg for circuit simulation in LTspice. It also references outputting a waveform similar to a report on fall time characteristics for a device modeling report with customer Samsung.
Digital Twins Computer Networking Paper Presentation.pptxaryanpankaj78
A Digital Twin in computer networking is a virtual representation of a physical network, used to simulate, analyze, and optimize network performance and reliability. It leverages real-time data to enhance network management, predict issues, and improve decision-making processes.
Tools & Techniques for Commissioning and Maintaining PV Systems W-Animations ...Transcat
Join us for this solutions-based webinar on the tools and techniques for commissioning and maintaining PV Systems. In this session, we'll review the process of building and maintaining a solar array, starting with installation and commissioning, then reviewing operations and maintenance of the system. This course will review insulation resistance testing, I-V curve testing, earth-bond continuity, ground resistance testing, performance tests, visual inspections, ground and arc fault testing procedures, and power quality analysis.
Fluke Solar Application Specialist Will White is presenting on this engaging topic:
Will has worked in the renewable energy industry since 2005, first as an installer for a small east coast solar integrator before adding sales, design, and project management to his skillset. In 2022, Will joined Fluke as a solar application specialist, where he supports their renewable energy testing equipment like IV-curve tracers, electrical meters, and thermal imaging cameras. Experienced in wind power, solar thermal, energy storage, and all scales of PV, Will has primarily focused on residential and small commercial systems. He is passionate about implementing high-quality, code-compliant installation techniques.
Software Engineering and Project Management - Software Testing + Agile Method...Prakhyath Rai
Software Testing: A Strategic Approach to Software Testing, Strategic Issues, Test Strategies for Conventional Software, Test Strategies for Object -Oriented Software, Validation Testing, System Testing, The Art of Debugging.
Agile Methodology: Before Agile – Waterfall, Agile Development.
Discover the latest insights on Data Driven Maintenance with our comprehensive webinar presentation. Learn about traditional maintenance challenges, the right approach to utilizing data, and the benefits of adopting a Data Driven Maintenance strategy. Explore real-world examples, industry best practices, and innovative solutions like FMECA and the D3M model. This presentation, led by expert Jules Oudmans, is essential for asset owners looking to optimize their maintenance processes and leverage digital technologies for improved efficiency and performance. Download now to stay ahead in the evolving maintenance landscape.
Generative AI Use cases applications solutions and implementation.pdfmahaffeycheryld
Generative AI solutions encompass a range of capabilities from content creation to complex problem-solving across industries. Implementing generative AI involves identifying specific business needs, developing tailored AI models using techniques like GANs and VAEs, and integrating these models into existing workflows. Data quality and continuous model refinement are crucial for effective implementation. Businesses must also consider ethical implications and ensure transparency in AI decision-making. Generative AI's implementation aims to enhance efficiency, creativity, and innovation by leveraging autonomous generation and sophisticated learning algorithms to meet diverse business challenges.
https://www.leewayhertz.com/generative-ai-use-cases-and-applications/
Use PyCharm for remote debugging of WSL on a Windo cf5c162d672e4e58b4dde5d797...shadow0702a
This document serves as a comprehensive step-by-step guide on how to effectively use PyCharm for remote debugging of the Windows Subsystem for Linux (WSL) on a local Windows machine. It meticulously outlines several critical steps in the process, starting with the crucial task of enabling permissions, followed by the installation and configuration of WSL.
The guide then proceeds to explain how to set up the SSH service within the WSL environment, an integral part of the process. Alongside this, it also provides detailed instructions on how to modify the inbound rules of the Windows firewall to facilitate the process, ensuring that there are no connectivity issues that could potentially hinder the debugging process.
The document further emphasizes on the importance of checking the connection between the Windows and WSL environments, providing instructions on how to ensure that the connection is optimal and ready for remote debugging.
It also offers an in-depth guide on how to configure the WSL interpreter and files within the PyCharm environment. This is essential for ensuring that the debugging process is set up correctly and that the program can be run effectively within the WSL terminal.
Additionally, the document provides guidance on how to set up breakpoints for debugging, a fundamental aspect of the debugging process which allows the developer to stop the execution of their code at certain points and inspect their program at those stages.
Finally, the document concludes by providing a link to a reference blog. This blog offers additional information and guidance on configuring the remote Python interpreter in PyCharm, providing the reader with a well-rounded understanding of the process.
Build the Next Generation of Apps with the Einstein 1 Platform.
Rejoignez Philippe Ozil pour une session de workshops qui vous guidera à travers les détails de la plateforme Einstein 1, l'importance des données pour la création d'applications d'intelligence artificielle et les différents outils et technologies que Salesforce propose pour vous apporter tous les bénéfices de l'IA.
Open Channel Flow: fluid flow with a free surfaceIndrajeet sahu
Open Channel Flow: This topic focuses on fluid flow with a free surface, such as in rivers, canals, and drainage ditches. Key concepts include the classification of flow types (steady vs. unsteady, uniform vs. non-uniform), hydraulic radius, flow resistance, Manning's equation, critical flow conditions, and energy and momentum principles. It also covers flow measurement techniques, gradually varied flow analysis, and the design of open channels. Understanding these principles is vital for effective water resource management and engineering applications.
Home security is of paramount importance in today's world, where we rely more on technology, home
security is crucial. Using technology to make homes safer and easier to control from anywhere is
important. Home security is important for the occupant’s safety. In this paper, we came up with a low cost,
AI based model home security system. The system has a user-friendly interface, allowing users to start
model training and face detection with simple keyboard commands. Our goal is to introduce an innovative
home security system using facial recognition technology. Unlike traditional systems, this system trains
and saves images of friends and family members. The system scans this folder to recognize familiar faces
and provides real-time monitoring. If an unfamiliar face is detected, it promptly sends an email alert,
ensuring a proactive response to potential security threats.
9. Mesh statistics :
Total grid points = 900
Total no. of elements = 1196
Min grid spacing (um) = 1.7841E-07
Max grid spacing (um) = 5.5372E-01 (r= 3.1036E+06)
Obtuse elements = 0 ( 0.0%)
Material Definitions
Index Name Regions
1 sio2 1
2 silicon 2
Constants :
Boltzmanns k = 8.61700E-05
charge = 1.60200E-19
permittivity = 8.85400E-14
electron mass= 9.10950E-31
Ambient temperature = 300.000
Thermal voltage = 0.025851
Material data
num r-perm Egap Affinity Ec offset Bulk qf k-therm Gen con
1 3.90 9.0000E+00 9.0000E-01 -3.2700E+00 0.0000E+00 2.5000E-01 0.0000E+00
2 11.80 1.1200E+00 4.1700E+00 0.0000E+00 0.0000E+00 1.4500E+00
4.0000E+13
Semiconductor data
num stats ni An** Ap** Nc Nv
10. 2 Boltz 9.963E+09 1.100E+02 3.000E+01 3.200E+19 2.030E+19
num gcb edb gcv eab w2d H-alphn
H-alphp
2 2.000E+00 5.000E-02 4.000E+00 4.500E-02 1.000E-03 3.000E-05
2.000E-07
Model flags :
Incomp. ionization = F
Band-gap narrowing = F
SRH recombination = T
Conc-dep lifetime = F
Auger recombination = F
Deep level traps = F
Radiative recomb = F
Impact ionization = F
Band-to-band tunnel = F
Trap-assist tunnel = F
Stimulated emission = F
Carrier-carr. scat. = F
Neutral imp. scat. = F
Ion-impurity scat. = T
Field dep. mobil = T
Gate fld dep mobil = F
Field dep. diff = F
Thermoelectric curr = T
ET ebal formulation = F
Model Types:
11. mat # II-scat CC-scat Fld mob Vsat Gate mob
2 n Analytic Dorkel Caughey Exponent SGS
p Analytic Dorkel Caughey Power SGS
mat # D(E) Energy Ce(T) BGN
2 n Lincut Const. P Slotboom
p Lincut Const. P Slotboom
Driving forces :
Mobility, parallel field = qfb
Mobility, gate field = exj
Diffusivity = qfb
Impact ionization = eoj
Default low-field mobilities/relax-times, vsat, w-kappa
mat # mobl0 tauw vsat(T0) kappa
2 n 1390. 2.0000E-13 1.0349E+07 1.500
p 470.0 2.0000E-13 8.3700E+06 1.500
Trap level data
mat # Type Et-Ei (eV) tau0 (n) tau0 (p) Ntrap
2 0 0.00 1.000E-09 1.000E-09 0.00
Velocity saturation coefficients
mat # coef 1 coef 2 coef 3 coef 4 coef 5
2 n 2.400E+07 0.800 0.500 0.00 0.00
p 8.370E+06 0.800 -0.520 0.00 0.00
Lattice scat. mobility coefficients
mat # coef 1 coef 2 coef 3 coef 4 coef 5
2 n 1.390E+03 -2.30 0.00 0.00 0.00
12. p 470. -2.20 0.00 0.00 0.00
Ion-impurity mobility coefficients
mat # coef 1 coef 2 coef 3 coef 4 coef 5
2 n 55.2 1.072E+17 0.733 -2.55 -0.570
p 49.7 1.606E+17 0.700 -2.55 -0.570
Field mobility coefficients
mat # coef 1 coef 2 coef 3 coef 4 coef 5
2 n 2.00 0.00 0.00 0.00 0.00
p 1.00 0.00 0.00 0.00 0.00
Field mobility coefficients (cont.)
mat # coef 6 coef 7 coef 8 coef 9 coef 10
2 n 0.00 0.00 0.00 0.00 0.00
p 0.00 0.00 0.00 0.00 0.00
Energy relaxation coefficients
mat # coef 1 coef 2 coef 3 coef 4 coef 5
2 n 1.00 0.00 0.00 0.00 0.00
p 1.00 0.00 0.00 0.00 0.00
Energy relaxation coefficients (cont.)
mat # coef 6 coef 7 coef 8 coef 9 coef 10
2 n 0.00 0.00 0.00 0.00 0.00
p 0.00 0.00 0.00 0.00 0.00
Misc energy trans coefficients
mat # coef 1 coef 2 coef 3 coef 4 coef 5
2 n 0.00 0.00 0.00 0.00 0.00
19. Electrode Voltage Electron Current Hole Current Conduction Current
(Volts) (Amps) (Amps) (Amps)
1 -0.4000 0.00000E+00 0.00000E+00 0.00000E+00
2 0.0000 -2.16268E-31 -2.75081E-22 -2.75081E-22
Electrode Flux Displacement Current Total Current
(Coul) (Amps) (Amps)
1 8.18498E-17 0.00000E+00 0.00000E+00
2 -1.75575E-31 0.00000E+00 -2.75081E-22
Convergence criterion completely met
Total cpu time for Newton equation assembly = 0.1667
Total cpu time for Newton linear solves = 0.0333 ( 0.0333)
Total cpu time for bias point = 0.2000
Total cpu time = 1.0000
Solution for bias:
V1 = -6.0000000E-01 V2 = 0.0000000E+00
Previous solution used as initial guess
o-itr i-itr psi-error n-error p-error
1 0 7.1140E-01 R( 0)
1 1 7.7073E+00 U( 1)
1 1 4.9521E-04 R( 1)
1 2* 4.5911E-01 U( 5)
1 2* 6.4867E-05 R( 1)
1 3% 7.2487E-02 U( 5)
1 3% 1.3521E-06 R( 1)
1 4* 1.4621E-03 U( 3)
1 4* 5.8431E-10 R( 1)
1 5* 5.9911E-07 U( 2)
20. 1 5* 6.2214E-13 R( 1)
1 0 1.0000E+00 R( 0)
1 1 7.1094E-15 U( 1)
1 1 3.8639E-02 R( 1)
1 0 1.0000E+00 R( 0)
1 1 4.4047E-15 U( 1)
1 1 3.0710E-02 R( 1)
2 0 1.1142E-10 R( 0)
2 1 1.7346E-13 U( 1)
2 1 1.1911E-10 R( 1)
2 0 1.0000E+00 R( 0)
2 1 7.3635E-15 U( 1)
2 1 3.5387E-02 R( 1)
2 0 1.0000E+00 R( 0)
2 1 2.5002E-15 U( 1)
2 1 4.0691E-02 R( 1)
1 0 6.5949E-14 3.4892E-18 2.0462E-15 R( 0)
1 1 1.2269E-15 1.4534E-15 1.5546E-15 U( 1)
1 1 3.6050E-14 1.9753E-17 1.5437E-14 R( 1)
Electrode Voltage Electron Current Hole Current Conduction Current
(Volts) (Amps) (Amps) (Amps)
1 -0.6000 0.00000E+00 0.00000E+00 0.00000E+00
2 0.0000 -1.97686E-32 3.39297E-22 3.39297E-22
Electrode Flux Displacement Current Total Current
(Coul) (Amps) (Amps)
1 5.30693E-17 0.00000E+00 0.00000E+00
2 -5.52320E-32 0.00000E+00 3.39297E-22
Convergence criterion completely met
Total cpu time for Newton equation assembly = 0.1667
Total cpu time for Newton linear solves = 0.0333 ( 0.0333)
Total cpu time for bias point = 0.2000
Total cpu time = 1.2000
22. 2 1 2.0242E-15 U( 1)
2 1 1.2520E-01 R( 1)
1 0 1.1018E-13 1.2136E-19 2.2354E-15 R( 0)
1 1 1.0915E-15 1.1446E-15 1.1015E-15 U( 1)
1 1 1.1031E-13 1.4526E-18 3.4702E-14 R( 1)
Electrode Voltage Electron Current Hole Current Conduction Current
(Volts) (Amps) (Amps) (Amps)
1 -0.8000 0.00000E+00 0.00000E+00 0.00000E+00
2 0.0000 -2.93067E-31 -5.88191E-22 -5.88191E-22
Electrode Flux Displacement Current Total Current
(Coul) (Amps) (Amps)
1 1.47597E-17 0.00000E+00 0.00000E+00
2 -3.51749E-32 0.00000E+00 -5.88191E-22
Convergence criterion completely met
Total cpu time for Newton equation assembly = 0.1667
Total cpu time for Newton linear solves = 0.0333 ( 0.0333)
Total cpu time for bias point = 0.2000
Total cpu time = 1.4000
Solution for bias:
V1 = -1.0000000E+00 V2 = 0.0000000E+00
Previous solution used as initial guess
o-itr i-itr psi-error n-error p-error
1 0 7.0788E-01 R( 0)
1 1 7.6857E+00 U( 1)
1 1 7.3523E-04 R( 1)
1 2% 5.1382E-01 U( 5)
24. Convergence criterion completely met
Total cpu time for Newton equation assembly = 0.1333
Total cpu time for Newton linear solves = 0.0333 ( 0.0333)
Total cpu time for bias point = 0.2000
Total cpu time = 1.6000
Solution for bias:
V1 = -1.2000000E+00 V2 = 0.0000000E+00
Previous solution used as initial guess
o-itr i-itr psi-error n-error p-error
1 0 7.0527E-01 R( 0)
1 1 7.6742E+00 U( 1)
1 1 4.3991E-04 R( 1)
1 2* 2.9633E-01 U( 4)
1 2* 4.6584E-05 R( 1)
1 3* 3.5949E-02 U( 4)
1 3* 6.1880E-07 R( 1)
1 4* 4.6597E-04 U( 4)
1 4* 1.0771E-10 R( 1)
1 5* 7.8880E-08 U( 4)
1 5* 1.0066E-12 R( 1)
1 0 1.0000E+00 R( 0)
1 1 9.4764E-15 U( 1)
1 1 1.5812E-02 R( 1)
1 0 1.0000E+00 R( 0)
1 1 4.2472E-15 U( 1)
1 1 5.9911E-02 R( 1)
2 0 1.0400E-10 R( 0)
2 1 5.4691E-15 U( 1)
2 1 1.4176E-10 R( 1)
25. 2 0 1.0000E+00 R( 0)
2 1 7.3817E-15 U( 1)
2 1 1.4061E-02 R( 1)
2 0 1.0000E+00 R( 0)
2 1 1.8465E-15 U( 1)
2 1 2.3273E-01 R( 1)
1 0 1.3723E-13 6.7214E-21 3.0250E-15 R( 0)
1 1 1.7757E-15 1.5771E-15 1.3014E-15 U( 1)
1 1 1.3723E-13 7.5624E-20 3.7540E-14 R( 1)
Electrode Voltage Electron Current Hole Current Conduction Current
(Volts) (Amps) (Amps) (Amps)
1 -1.2000 0.00000E+00 0.00000E+00 0.00000E+00
2 0.0000 -1.27248E-31 7.48865E-33 -1.19759E-31
Electrode Flux Displacement Current Total Current
(Coul) (Amps) (Amps)
1 -9.27876E-17 0.00000E+00 0.00000E+00
2 -1.51177E-32 0.00000E+00 -1.19759E-31
Convergence criterion completely met
Total cpu time for Newton equation assembly = 0.1333
Total cpu time for Newton linear solves = 0.0333 ( 0.0333)
Total cpu time for bias point = 0.1667
Total cpu time = 1.7667
Solution for bias:
V1 = -1.4000000E+00 V2 = 0.0000000E+00
Previous solution used as initial guess
o-itr i-itr psi-error n-error p-error
27. (Coul) (Amps) (Amps)
1 -1.54142E-16 0.00000E+00 0.00000E+00
2 -1.51177E-32 0.00000E+00 -1.16591E-22
Convergence criterion completely met
Total cpu time for Newton equation assembly = 0.1667
Total cpu time for Newton linear solves = 0.0333 ( 0.0333)
Total cpu time for bias point = 0.2000
Total cpu time = 1.9667
Solution for bias:
V1 = -1.6000000E+00 V2 = 0.0000000E+00
Previous solution used as initial guess
o-itr i-itr psi-error n-error p-error
1 0 6.9909E-01 R( 0)
1 1 7.6651E+00 U( 1)
1 1 1.8662E-04 R( 1)
1 2* 9.0573E-02 U( 4)
1 2* 6.1574E-06 R( 1)
1 3* 3.0699E-03 U( 4)
1 3* 7.4800E-09 R( 1)
1 4* 3.5783E-06 U( 4)
1 4* 1.6471E-12 R( 1)
1 0 1.0000E+00 R( 0)
1 1 8.5614E-15 U( 1)
1 1 1.3943E-02 R( 1)
1 0 1.0000E+00 R( 0)
1 1 3.3332E-15 U( 1)
1 1 6.7534E-02 R( 1)
2 0 7.3228E-11 R( 0)
28. 2 1 5.0231E-12 U( 1)
2 1 4.1510E-11 R( 1)
2 0 1.0000E+00 R( 0)
2 1 9.2495E-15 U( 1)
2 1 1.5281E-02 R( 1)
2 0 1.0000E+00 R( 0)
2 1 3.1629E-15 U( 1)
2 1 2.1855E-01 R( 1)
1 0 9.4211E-14 2.3852E-21 3.6508E-15 R( 0)
1 1 4.6795E-15 4.6948E-15 3.6807E-15 U( 1)
1 1 1.2528E-13 2.7265E-20 3.5087E-14 R( 1)
Electrode Voltage Electron Current Hole Current Conduction Current
(Volts) (Amps) (Amps) (Amps)
1 -1.6000 0.00000E+00 0.00000E+00 0.00000E+00
2 0.0000 -1.67168E-31 -1.16591E-22 -1.16591E-22
Electrode Flux Displacement Current Total Current
(Coul) (Amps) (Amps)
1 -2.17538E-16 0.00000E+00 0.00000E+00
2 -1.51177E-32 0.00000E+00 -1.16591E-22
Convergence criterion completely met
Total cpu time for Newton equation assembly = 0.1333
Total cpu time for Newton linear solves = 0.0333 ( 0.0333)
Total cpu time for bias point = 0.2000
Total cpu time = 2.1667
Solution for bias:
V1 = -1.8000000E+00 V2 = 0.0000000E+00
Previous solution used as initial guess
30. (Coul) (Amps) (Amps)
1 -2.82160E-16 0.00000E+00 0.00000E+00
2 -1.51177E-32 0.00000E+00 -2.33182E-22
Convergence criterion completely met
Total cpu time for Newton equation assembly = 0.0667
Total cpu time for Newton linear solves = 0.1000 ( 0.1000)
Total cpu time for bias point = 0.1667
Total cpu time = 2.3333
Solution for bias:
V1 = -2.0000000E+00 V2 = 0.0000000E+00
Previous solution used as initial guess
o-itr i-itr psi-error n-error p-error
1 0 6.9251E-01 R( 0)
1 1 7.6622E+00 U( 1)
1 1 1.3046E-04 R( 1)
1 2* 3.8741E-02 U( 4)
1 2* 1.7349E-06 R( 1)
1 3* 5.5244E-04 U( 4)
1 3* 3.7407E-10 R( 1)
1 4* 1.1859E-07 U( 4)
1 4* 7.6737E-13 R( 1)
1 0 1.0000E+00 R( 0)
1 1 1.0115E-14 U( 1)
1 1 1.6390E-02 R( 1)
1 0 1.0000E+00 R( 0)
1 1 3.9134E-15 U( 1)
1 1 6.0024E-02 R( 1)
2 0 2.1555E-11 R( 0)
31. 2 1 6.2223E-15 U( 1)
2 1 6.0544E-11 R( 1)
2 0 1.0000E+00 R( 0)
2 1 8.8694E-15 U( 1)
2 1 1.5096E-02 R( 1)
2 0 1.0000E+00 R( 0)
2 1 1.6930E-15 U( 1)
2 1 2.4066E-01 R( 1)
1 0 2.1955E-13 1.9879E-21 3.7240E-15 R( 0)
1 1 3.6782E-15 2.0744E-15 2.2446E-15 U( 1)
1 1 1.9654E-13 2.1254E-20 4.9150E-14 R( 1)
Electrode Voltage Electron Current Hole Current Conduction Current
(Volts) (Amps) (Amps) (Amps)
1 -2.0000 0.00000E+00 0.00000E+00 0.00000E+00
2 0.0000 -1.67168E-31 -2.33182E-22 -2.33182E-22
Electrode Flux Displacement Current Total Current
(Coul) (Amps) (Amps)
1 -3.47583E-16 0.00000E+00 0.00000E+00
2 -1.51177E-32 0.00000E+00 -2.33182E-22
Convergence criterion completely met
Total cpu time for Newton equation assembly = 0.1333
Total cpu time for Newton linear solves = 0.0333 ( 0.0333)
Total cpu time for bias point = 0.2000
Total cpu time = 2.5333
Solution for bias:
V1 = -2.2000000E+00 V2 = 0.0000000E+00
Previous solution used as initial guess
33. (Coul) (Amps) (Amps)
1 -4.13569E-16 0.00000E+00 0.00000E+00
2 -1.51177E-32 0.00000E+00 -2.33182E-22
Convergence criterion completely met
Total cpu time for Newton equation assembly = 0.1333
Total cpu time for Newton linear solves = 0.0667 ( 0.0667)
Total cpu time for bias point = 0.2000
Total cpu time = 2.7333
Solution for bias:
V1 = -2.4000000E+00 V2 = 0.0000000E+00
Previous solution used as initial guess
o-itr i-itr psi-error n-error p-error
1 0 6.8582E-01 R( 0)
1 1 7.6609E+00 U( 1)
1 1 1.0637E-04 R( 1)
1 2% 2.0816E-02 U( 4)
1 2% 7.4204E-07 R( 1)
1 3* 1.5886E-04 U( 2)
1 3* 4.5621E-11 R( 1)
1 4% 9.9227E-09 U( 3)
1 4% 1.9136E-12 R( 1)
1 0 1.0000E+00 R( 0)
1 1 8.6235E-15 U( 1)
1 1 1.8438E-02 R( 1)
1 0 1.0000E+00 R( 0)
1 1 3.6649E-15 U( 1)
1 1 3.8513E-02 R( 1)
2 0 3.9306E-11 R( 0)
34. 2 1 6.5710E-15 U( 1)
2 1 5.3454E-11 R( 1)
2 0 1.0000E+00 R( 0)
2 1 7.6996E-15 U( 1)
2 1 2.1647E-02 R( 1)
2 0 1.0000E+00 R( 0)
2 1 2.2120E-15 U( 1)
2 1 1.9207E-01 R( 1)
1 0 2.6767E-13 1.7969E-21 3.4669E-15 R( 0)
1 1 6.7300E-15 3.2849E-15 3.1561E-15 U( 1)
1 1 2.0902E-13 2.0309E-20 7.6267E-14 R( 1)
Electrode Voltage Electron Current Hole Current Conduction Current
(Volts) (Amps) (Amps) (Amps)
1 -2.4000 0.00000E+00 0.00000E+00 0.00000E+00
2 0.0000 -1.67168E-31 -2.33182E-22 -2.33182E-22
Electrode Flux Displacement Current Total Current
(Coul) (Amps) (Amps)
1 -4.79967E-16 0.00000E+00 0.00000E+00
2 -1.51177E-32 0.00000E+00 -2.33182E-22
Convergence criterion completely met
Total cpu time for Newton equation assembly = 0.1667
Total cpu time for Newton linear solves = 0.0000 ( 0.0000)
Total cpu time for bias point = 0.1667
Total cpu time = 2.9000
Solution for bias:
V1 = -2.6000000E+00 V2 = 0.0000000E+00
Previous solution used as initial guess
36. (Coul) (Amps) (Amps)
1 -5.46681E-16 0.00000E+00 0.00000E+00
2 -1.51177E-32 0.00000E+00 -2.33182E-22
Convergence criterion completely met
Total cpu time for Newton equation assembly = 0.1333
Total cpu time for Newton linear solves = 0.0667 ( 0.0667)
Total cpu time for bias point = 0.2000
Total cpu time = 3.1000
Solution for bias:
V1 = -2.8000000E+00 V2 = 0.0000000E+00
Previous solution used as initial guess
o-itr i-itr psi-error n-error p-error
1 0 6.7912E-01 R( 0)
1 1 7.6602E+00 U( 1)
1 1 9.1607E-05 R( 1)
1 2* 1.2839E-02 U( 3)
1 2* 3.9137E-07 R( 1)
1 3* 6.0369E-05 U( 3)
1 3* 9.2254E-12 R( 1)
1 4* 1.4401E-09 U( 4)
1 4* 1.8325E-12 R( 1)
1 0 1.0000E+00 R( 0)
1 1 7.9934E-15 U( 1)
1 1 1.6456E-02 R( 1)
1 0 1.0000E+00 R( 0)
1 1 4.6188E-15 U( 1)
1 1 5.9356E-02 R( 1)
2 0 2.9732E-11 R( 0)
37. 2 1 8.0909E-15 U( 1)
2 1 2.3759E-11 R( 1)
2 0 1.0000E+00 R( 0)
2 1 7.7434E-15 U( 1)
2 1 2.3809E-02 R( 1)
2 0 1.0000E+00 R( 0)
2 1 1.8422E-15 U( 1)
2 1 2.3869E-01 R( 1)
1 0 1.5211E-13 1.9249E-21 4.4557E-15 R( 0)
1 1 6.9985E-15 2.2901E-15 2.4868E-15 U( 1)
1 1 1.5239E-13 1.8950E-20 9.2082E-14 R( 1)
Electrode Voltage Electron Current Hole Current Conduction Current
(Volts) (Amps) (Amps) (Amps)
1 -2.8000 0.00000E+00 0.00000E+00 0.00000E+00
2 0.0000 -1.67168E-31 -2.33182E-22 -2.33182E-22
Electrode Flux Displacement Current Total Current
(Coul) (Amps) (Amps)
1 -6.13644E-16 0.00000E+00 0.00000E+00
2 -1.51177E-32 0.00000E+00 -2.33182E-22
Convergence criterion completely met
Total cpu time for Newton equation assembly = 0.1667
Total cpu time for Newton linear solves = -0.0000 ( -0.0000)
Total cpu time for bias point = 0.1667
Total cpu time = 3.2667
Solution for bias:
V1 = -3.0000000E+00 V2 = 0.0000000E+00
Previous solution used as initial guess
39. (Coul) (Amps) (Amps)
1 -6.80807E-16 0.00000E+00 0.00000E+00
2 -1.51177E-32 0.00000E+00 -2.33182E-22
Convergence criterion completely met
Total cpu time for Newton equation assembly = 0.1667
Total cpu time for Newton linear solves = 0.0333 ( 0.0333)
Total cpu time for bias point = 0.2000
Total cpu time = 3.4667
Solution for bias:
V1 = -3.0000000E+00 V2 = 0.0000000E+00
Previous solution used as initial guess
o-itr i-itr psi-error n-error p-error
1 0 2.4585E-11 R( 0)
1 1 1.9899E-14 U( 1)
1 1 2.4501E-11 R( 1)
1 0 1.0000E+00 R( 0)
1 1 4.5704E-15 U( 1)
1 1 2.7447E-02 R( 1)
1 0 1.0000E+00 R( 0)
1 1 2.4880E-15 U( 1)
1 1 5.4712E-02 R( 1)
2 0 2.4501E-11 R( 0)
2 1 6.8994E-15 U( 1)
2 1 2.4498E-11 R( 1)
2 0 1.0000E+00 R( 0)
2 1 5.6458E-15 U( 1)
2 1 2.8232E-02 R( 1)
2 0 1.0000E+00 R( 0)
40. 2 1 1.1964E-15 U( 1)
2 1 3.0275E-01 R( 1)
1 0 1.7401E-13 1.9661E-21 3.8911E-15 R( 0)
1 1 6.9165E-15 1.7704E-15 2.1586E-15 U( 1)
1 1 1.7401E-13 1.8016E-20 8.0365E-14 R( 1)
Electrode Voltage Electron Current Hole Current Conduction Current
(Volts) (Amps) (Amps) (Amps)
1 -3.0000 0.00000E+00 0.00000E+00 0.00000E+00
2 0.0000 -1.67168E-31 -2.33182E-22 -2.33182E-22
Electrode Flux Displacement Current Total Current
(Coul) (Amps) (Amps)
1 -6.80807E-16 0.00000E+00 0.00000E+00
2 -1.51177E-32 0.00000E+00 -2.33182E-22
Convergence criterion completely met
Total cpu time for Newton equation assembly = 0.1333
Total cpu time for Newton linear solves = 0.0000 ( 0.0000)
Total cpu time for bias point = 0.1667
Total cpu time = 3.6333
Ac analysis :
Ac voltage = 2.585100E-03
Frequency = 1.000000E+00 Hz
Electrode # 1
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 -7.53395E-27 -5.46168E-18
2 2.46273E-18 5.46168E-18 -4.88307E-28 2.20183E-28
41. Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y11 -7.53395E-27 -5.46168E-18 -2.91438E-24 -3.36255E-16
Y21 2.46273E-18 5.46168E-18 9.52662E-16 3.36255E-16
Electrode # 2
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 7.53395E-27 5.46168E-18
2 -5.00280E-17 -5.46168E-18 4.88307E-28 -4.47280E-27
Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y12 7.53395E-27 5.46168E-18 2.91438E-24 3.36255E-16
Y22 -5.00280E-17 -5.46168E-18 -1.93524E-14 -3.36255E-16
Total cpu time for Newton equation assembly = 0.0333
Total cpu time for Newton linear solves = 0.0333 ( 0.0333)
Total cpu time for ac analysis = 0.0667
Total cpu time = 3.7000
Solution for bias:
V1 = -2.9389345E+00 V2 = 0.0000000E+00
Previous solution used as initial guess
o-itr i-itr psi-error n-error p-error
1 0 8.3069E-01 R( 0)
1 1 2.3387E+00 U( 1)
43. Total cpu time for Newton linear solves = -0.0000 ( -0.0000)
Total cpu time for bias point = 0.1667
Total cpu time = 3.8667
Ac analysis :
Ac voltage = 2.585100E-03
Frequency = 1.000000E+00 Hz
Electrode # 1
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 -7.52269E-27 -5.45748E-18
2 3.46230E-18 5.45748E-18 -4.87932E-28 3.09550E-28
Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y11 -7.52269E-27 -5.45748E-18 -2.91002E-24 -3.35997E-16
Y21 3.46230E-18 5.45748E-18 1.33933E-15 3.35997E-16
Electrode # 2
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 7.52269E-27 5.45748E-18
2 -1.91631E-17 -5.45748E-18 4.87932E-28 -1.71329E-27
Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y12 7.52269E-27 5.45748E-18 2.91002E-24 3.35997E-16
Y22 -1.91631E-17 -5.45748E-18 -7.41290E-15 -3.35997E-16
44. Total cpu time for Newton equation assembly = 0.0333
Total cpu time for Newton linear solves = 0.0333 ( 0.0333)
Total cpu time for ac analysis = 0.0667
Total cpu time = 3.9333
Solution for bias:
V1 = -2.8778690E+00 V2 = 0.0000000E+00
Previous solution used as initial guess
o-itr i-itr psi-error n-error p-error
1 0 8.2687E-01 R( 0)
1 1 2.3387E+00 U( 1)
1 1 2.8670E-05 R( 1)
1 2* 9.2805E-04 U( 3)
1 2* 8.4590E-09 R( 1)
1 3* 3.0596E-07 U( 3)
1 3* 8.3324E-12 R( 1)
1 0 1.0000E+00 R( 0)
1 1 1.0464E-14 U( 1)
1 1 1.6061E-02 R( 1)
1 0 1.0000E+00 R( 0)
1 1 6.3595E-15 U( 1)
1 1 5.4065E-02 R( 1)
2 0 3.2516E-11 R( 0)
2 1 4.3515E-14 U( 1)
2 1 4.7055E-11 R( 1)
2 0 1.0000E+00 R( 0)
2 1 7.6370E-15 U( 1)
2 1 2.0200E-02 R( 1)
2 0 1.0000E+00 R( 0)
45. 2 1 1.3495E-15 U( 1)
2 1 1.9959E-01 R( 1)
1 0 3.1408E-13 1.9924E-21 3.5815E-15 R( 0)
1 1 7.4053E-15 3.0611E-15 3.5880E-15 U( 1)
1 1 3.1490E-13 1.9027E-20 7.7703E-14 R( 1)
Electrode Voltage Electron Current Hole Current Conduction Current
(Volts) (Amps) (Amps) (Amps)
1 -2.8779 0.00000E+00 0.00000E+00 0.00000E+00
2 0.0000 -1.67168E-31 -2.33182E-22 -2.33182E-22
Electrode Flux Displacement Current Total Current
(Coul) (Amps) (Amps)
1 -6.39772E-16 0.00000E+00 0.00000E+00
2 -1.51177E-32 0.00000E+00 -2.33182E-22
Convergence criterion completely met
Total cpu time for Newton equation assembly = 0.1333
Total cpu time for Newton linear solves = 0.0333 ( 0.0333)
Total cpu time for bias point = 0.1667
Total cpu time = 4.1000
Ac analysis :
Ac voltage = 2.585100E-03
Frequency = 1.000000E+00 Hz
Electrode # 1
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 -7.51076E-27 -5.45304E-18
2 3.23867E-18 5.45304E-18 -4.87534E-28 2.89557E-28
46. Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y11 -7.51076E-27 -5.45304E-18 -2.90540E-24 -3.35723E-16
Y21 3.23867E-18 5.45304E-18 1.25282E-15 3.35723E-16
Electrode # 2
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 7.51076E-27 5.45304E-18
2 3.34473E-17 -5.45304E-18 4.87534E-28 2.99039E-27
Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y12 7.51076E-27 5.45304E-18 2.90540E-24 3.35723E-16
Y22 3.34473E-17 -5.45304E-18 1.29385E-14 -3.35723E-16
Total cpu time for Newton equation assembly = 0.0333
Total cpu time for Newton linear solves = -0.0000 ( -0.0000)
Total cpu time for ac analysis = 0.0667
Total cpu time = 4.1667
Solution for bias:
V1 = -2.8168034E+00 V2 = 0.0000000E+00
Previous solution used as initial guess
o-itr i-itr psi-error n-error p-error
1 0 8.2304E-01 R( 0)
1 1 2.3388E+00 U( 1)
48. Total cpu time for Newton linear solves = -0.0000 ( -0.0000)
Total cpu time for bias point = 0.1667
Total cpu time = 4.3333
Ac analysis :
Ac voltage = 2.585100E-03
Frequency = 1.000000E+00 Hz
Electrode # 1
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 -7.49810E-27 -5.44832E-18
2 3.65049E-18 5.44832E-18 -4.87112E-28 3.26376E-28
Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y11 -7.49810E-27 -5.44832E-18 -2.90051E-24 -3.35432E-16
Y21 3.65049E-18 5.44832E-18 1.41213E-15 3.35432E-16
Electrode # 2
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 7.49810E-27 5.44832E-18
2 -1.55270E-17 -5.44832E-18 4.87112E-28 -1.38821E-27
Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y12 7.49810E-27 5.44832E-18 2.90051E-24 3.35432E-16
Y22 -1.55270E-17 -5.44832E-18 -6.00636E-15 -3.35432E-16
49. Total cpu time for Newton equation assembly = 0.0333
Total cpu time for Newton linear solves = 0.0333 ( 0.0333)
Total cpu time for ac analysis = 0.0667
Total cpu time = 4.4000
Solution for bias:
V1 = -2.7557379E+00 V2 = 0.0000000E+00
Previous solution used as initial guess
o-itr i-itr psi-error n-error p-error
1 0 8.1922E-01 R( 0)
1 1 2.3388E+00 U( 1)
1 1 2.9200E-05 R( 1)
1 2* 1.0471E-03 U( 3)
1 2* 9.6999E-09 R( 1)
1 3* 3.8853E-07 U( 3)
1 3* 5.1351E-12 R( 1)
1 0 1.0000E+00 R( 0)
1 1 9.1257E-15 U( 1)
1 1 1.9346E-02 R( 1)
1 0 1.0000E+00 R( 0)
1 1 4.8432E-15 U( 1)
1 1 7.1527E-02 R( 1)
2 0 2.1610E-11 R( 0)
2 1 5.9003E-14 U( 1)
2 1 2.1515E-11 R( 1)
2 0 1.0000E+00 R( 0)
2 1 8.7210E-15 U( 1)
2 1 2.1472E-02 R( 1)
2 0 1.0000E+00 R( 0)
50. 2 1 1.1421E-15 U( 1)
2 1 2.0638E-01 R( 1)
1 0 1.3441E-13 1.7327E-21 3.7783E-15 R( 0)
1 1 5.1811E-15 2.6836E-15 2.3482E-15 U( 1)
1 1 1.3438E-13 1.9465E-20 7.5747E-14 R( 1)
Electrode Voltage Electron Current Hole Current Conduction Current
(Volts) (Amps) (Amps) (Amps)
1 -2.7557 0.00000E+00 0.00000E+00 0.00000E+00
2 0.0000 -1.67168E-31 -2.33182E-22 -2.33182E-22
Electrode Flux Displacement Current Total Current
(Coul) (Amps) (Amps)
1 -5.98806E-16 0.00000E+00 0.00000E+00
2 -1.51177E-32 0.00000E+00 -2.33182E-22
Convergence criterion completely met
Total cpu time for Newton equation assembly = 0.1667
Total cpu time for Newton linear solves = -0.0000 ( -0.0000)
Total cpu time for bias point = 0.1667
Total cpu time = 4.5667
Ac analysis :
Ac voltage = 2.585100E-03
Frequency = 1.000000E+00 Hz
Electrode # 1
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 -7.48466E-27 -5.44329E-18
2 2.91127E-18 5.44329E-18 -4.86663E-28 2.60285E-28
51. Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y11 -7.48466E-27 -5.44329E-18 -2.89531E-24 -3.35123E-16
Y21 2.91127E-18 5.44329E-18 1.12617E-15 3.35123E-16
Electrode # 2
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 7.48466E-27 5.44329E-18
2 -3.94305E-18 -5.44329E-18 4.86663E-28 -3.52533E-28
Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y12 7.48466E-27 5.44329E-18 2.89531E-24 3.35123E-16
Y22 -3.94305E-18 -5.44329E-18 -1.52530E-15 -3.35123E-16
Total cpu time for Newton equation assembly = 0.0333
Total cpu time for Newton linear solves = 0.0333 ( 0.0333)
Total cpu time for ac analysis = 0.0667
Total cpu time = 4.6333
Solution for bias:
V1 = -2.6946724E+00 V2 = 0.0000000E+00
Previous solution used as initial guess
o-itr i-itr psi-error n-error p-error
1 0 8.1541E-01 R( 0)
1 1 2.3388E+00 U( 1)
53. Total cpu time for Newton linear solves = -0.0000 ( -0.0000)
Total cpu time for bias point = 0.1667
Total cpu time = 4.8000
Ac analysis :
Ac voltage = 2.585100E-03
Frequency = 1.000000E+00 Hz
Electrode # 1
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 -7.47034E-27 -5.43795E-18
2 2.84201E-18 5.43795E-18 -4.86185E-28 2.54093E-28
Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y11 -7.47034E-27 -5.43795E-18 -2.88977E-24 -3.34794E-16
Y21 2.84201E-18 5.43795E-18 1.09938E-15 3.34794E-16
Electrode # 2
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 7.47034E-27 5.43795E-18
2 2.08364E-18 -5.43795E-18 4.86185E-28 1.86289E-28
Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y12 7.47034E-27 5.43795E-18 2.88977E-24 3.34794E-16
Y22 2.08364E-18 -5.43795E-18 8.06019E-16 -3.34794E-16
54. Total cpu time for Newton equation assembly = 0.0333
Total cpu time for Newton linear solves = 0.0333 ( 0.0333)
Total cpu time for ac analysis = 0.0667
Total cpu time = 4.8667
Solution for bias:
V1 = -2.6336069E+00 V2 = 0.0000000E+00
Previous solution used as initial guess
o-itr i-itr psi-error n-error p-error
1 0 8.1159E-01 R( 0)
1 1 2.3388E+00 U( 1)
1 1 2.9779E-05 R( 1)
1 2* 1.1900E-03 U( 3)
1 2* 1.1219E-08 R( 1)
1 3* 5.0049E-07 U( 3)
1 3* 6.8101E-12 R( 1)
1 0 1.0000E+00 R( 0)
1 1 1.1173E-14 U( 1)
1 1 2.0680E-02 R( 1)
1 0 1.0000E+00 R( 0)
1 1 5.6334E-15 U( 1)
1 1 4.6519E-02 R( 1)
2 0 3.1048E-11 R( 0)
2 1 9.7343E-14 U( 1)
2 1 3.4818E-11 R( 1)
2 0 1.0000E+00 R( 0)
2 1 8.1540E-15 U( 1)
2 1 1.6872E-02 R( 1)
2 0 1.0000E+00 R( 0)
55. 2 1 1.9045E-15 U( 1)
2 1 2.7631E-01 R( 1)
1 0 2.0267E-13 1.6629E-21 3.6277E-15 R( 0)
1 1 6.8886E-15 3.7595E-15 3.3739E-15 U( 1)
1 1 9.7738E-14 1.6674E-20 7.2519E-14 R( 1)
Electrode Voltage Electron Current Hole Current Conduction Current
(Volts) (Amps) (Amps) (Amps)
1 -2.6336 0.00000E+00 0.00000E+00 0.00000E+00
2 0.0000 -1.67168E-31 -2.33182E-22 -2.33182E-22
Electrode Flux Displacement Current Total Current
(Coul) (Amps) (Amps)
1 -5.57917E-16 0.00000E+00 0.00000E+00
2 -1.51177E-32 0.00000E+00 -2.33182E-22
Convergence criterion completely met
Total cpu time for Newton equation assembly = 0.0667
Total cpu time for Newton linear solves = 0.0667 ( 0.0667)
Total cpu time for bias point = 0.1667
Total cpu time = 5.0333
Ac analysis :
Ac voltage = 2.585100E-03
Frequency = 1.000000E+00 Hz
Electrode # 1
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 -7.45507E-27 -5.43224E-18
2 2.22015E-18 5.43224E-18 -4.85674E-28 1.98495E-28
56. Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y11 -7.45507E-27 -5.43224E-18 -2.88386E-24 -3.34442E-16
Y21 2.22015E-18 5.43224E-18 8.58825E-16 3.34442E-16
Electrode # 2
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 7.45507E-27 5.43224E-18
2 -2.41137E-17 -5.43224E-18 4.85674E-28 -2.15591E-27
Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y12 7.45507E-27 5.43224E-18 2.88386E-24 3.34442E-16
Y22 -2.41137E-17 -5.43224E-18 -9.32794E-15 -3.34442E-16
Total cpu time for Newton equation assembly = 0.0333
Total cpu time for Newton linear solves = 0.0333 ( 0.0333)
Total cpu time for ac analysis = 0.0667
Total cpu time = 5.1000
Solution for bias:
V1 = -2.5725413E+00 V2 = 0.0000000E+00
Previous solution used as initial guess
o-itr i-itr psi-error n-error p-error
1 0 8.0779E-01 R( 0)
1 1 2.3388E+00 U( 1)
58. Total cpu time for Newton linear solves = -0.0000 ( -0.0000)
Total cpu time for bias point = 0.1667
Total cpu time = 5.2667
Ac analysis :
Ac voltage = 2.585100E-03
Frequency = 1.000000E+00 Hz
Electrode # 1
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 -7.43874E-27 -5.42613E-18
2 2.12102E-18 5.42613E-18 -4.85128E-28 1.89632E-28
Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y11 -7.43874E-27 -5.42613E-18 -2.87755E-24 -3.34066E-16
Y21 2.12102E-18 5.42613E-18 8.20480E-16 3.34066E-16
Electrode # 2
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 7.43874E-27 5.42613E-18
2 -4.08181E-17 -5.42613E-18 4.85128E-28 -3.64938E-27
Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y12 7.43874E-27 5.42613E-18 2.87755E-24 3.34066E-16
Y22 -4.08181E-17 -5.42613E-18 -1.57898E-14 -3.34066E-16
59. Total cpu time for Newton equation assembly = 0.0333
Total cpu time for Newton linear solves = 0.0333 ( 0.0333)
Total cpu time for ac analysis = 0.0667
Total cpu time = 5.3333
Solution for bias:
V1 = -2.5114758E+00 V2 = 0.0000000E+00
Previous solution used as initial guess
o-itr i-itr psi-error n-error p-error
1 0 8.0398E-01 R( 0)
1 1 2.3389E+00 U( 1)
1 1 3.0415E-05 R( 1)
1 2* 1.3637E-03 U( 3)
1 2* 1.3106E-08 R( 1)
1 3* 6.5512E-07 U( 3)
1 3* 8.2636E-12 R( 1)
1 0 1.0000E+00 R( 0)
1 1 9.2083E-15 U( 1)
1 1 1.7632E-02 R( 1)
1 0 1.0000E+00 R( 0)
1 1 6.6237E-15 U( 1)
1 1 7.0719E-02 R( 1)
2 0 4.1032E-11 R( 0)
2 1 1.6526E-13 U( 1)
2 1 3.3602E-11 R( 1)
2 0 1.0000E+00 R( 0)
2 1 7.7029E-15 U( 1)
2 1 1.5059E-02 R( 1)
2 0 1.0000E+00 R( 0)
60. 2 1 2.2136E-15 U( 1)
2 1 1.3881E-01 R( 1)
1 0 1.8128E-13 1.7359E-21 3.9017E-15 R( 0)
1 1 7.3509E-15 2.9144E-15 3.2600E-15 U( 1)
1 1 1.6654E-13 1.9547E-20 8.5833E-14 R( 1)
Electrode Voltage Electron Current Hole Current Conduction Current
(Volts) (Amps) (Amps) (Amps)
1 -2.5115 0.00000E+00 0.00000E+00 0.00000E+00
2 0.0000 -1.67168E-31 -2.33182E-22 -2.33182E-22
Electrode Flux Displacement Current Total Current
(Coul) (Amps) (Amps)
1 -5.17118E-16 0.00000E+00 0.00000E+00
2 -1.51177E-32 0.00000E+00 -2.33182E-22
Convergence criterion completely met
Total cpu time for Newton equation assembly = 0.0667
Total cpu time for Newton linear solves = 0.0667 ( 0.0667)
Total cpu time for bias point = 0.1667
Total cpu time = 5.5000
Ac analysis :
Ac voltage = 2.585100E-03
Frequency = 1.000000E+00 Hz
Electrode # 1
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 -7.42126E-27 -5.41958E-18
2 2.80995E-18 5.41958E-18 -4.84543E-28 2.51227E-28
61. Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y11 -7.42126E-27 -5.41958E-18 -2.87078E-24 -3.33663E-16
Y21 2.80995E-18 5.41958E-18 1.08698E-15 3.33663E-16
Electrode # 2
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 7.42126E-27 5.41958E-18
2 -8.33011E-18 -5.41958E-18 4.84543E-28 -7.44761E-28
Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y12 7.42126E-27 5.41958E-18 2.87078E-24 3.33663E-16
Y22 -8.33011E-18 -5.41958E-18 -3.22236E-15 -3.33663E-16
Total cpu time for Newton equation assembly = 0.0333
Total cpu time for Newton linear solves = 0.0333 ( 0.0333)
Total cpu time for ac analysis = 0.0667
Total cpu time = 5.5667
Solution for bias:
V1 = -2.4504103E+00 V2 = 0.0000000E+00
Previous solution used as initial guess
o-itr i-itr psi-error n-error p-error
1 0 8.0019E-01 R( 0)
1 1 2.3389E+00 U( 1)
63. Total cpu time for Newton linear solves = 0.0000 ( 0.0000)
Total cpu time for bias point = 0.1667
Total cpu time = 5.7333
Ac analysis :
Ac voltage = 2.585100E-03
Frequency = 1.000000E+00 Hz
Electrode # 1
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 -7.40249E-27 -5.41254E-18
2 2.85323E-18 5.41254E-18 -4.83914E-28 2.55096E-28
Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y11 -7.40249E-27 -5.41254E-18 -2.86352E-24 -3.33230E-16
Y21 2.85323E-18 5.41254E-18 1.10372E-15 3.33230E-16
Electrode # 2
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 7.40249E-27 5.41254E-18
2 -1.53815E-17 -5.41254E-18 4.83914E-28 -1.37520E-27
Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y12 7.40249E-27 5.41254E-18 2.86352E-24 3.33230E-16
Y22 -1.53815E-17 -5.41254E-18 -5.95007E-15 -3.33230E-16
64. Total cpu time for Newton equation assembly = 0.0333
Total cpu time for Newton linear solves = 0.0333 ( 0.0333)
Total cpu time for ac analysis = 0.0667
Total cpu time = 5.8000
Solution for bias:
V1 = -2.3893448E+00 V2 = 0.0000000E+00
Previous solution used as initial guess
o-itr i-itr psi-error n-error p-error
1 0 7.9640E-01 R( 0)
1 1 2.3389E+00 U( 1)
1 1 3.1117E-05 R( 1)
1 2* 1.5773E-03 U( 3)
1 2* 1.5488E-08 R( 1)
1 3* 8.7317E-07 U( 3)
1 3* 6.8732E-12 R( 1)
1 0 1.0000E+00 R( 0)
1 1 8.6196E-15 U( 1)
1 1 1.7010E-02 R( 1)
1 0 1.0000E+00 R( 0)
1 1 5.2854E-15 U( 1)
1 1 4.4310E-02 R( 1)
2 0 3.7396E-11 R( 0)
2 1 2.9647E-13 U( 1)
2 1 3.9543E-11 R( 1)
2 0 1.0000E+00 R( 0)
2 1 7.9839E-15 U( 1)
2 1 1.9913E-02 R( 1)
2 0 1.0000E+00 R( 0)
65. 2 1 2.7803E-15 U( 1)
2 1 1.5455E-01 R( 1)
1 0 1.9655E-13 1.9302E-21 3.6101E-15 R( 0)
1 1 6.6292E-15 2.3262E-15 2.6790E-15 U( 1)
1 1 2.2421E-13 2.0809E-20 6.8470E-14 R( 1)
Electrode Voltage Electron Current Hole Current Conduction Current
(Volts) (Amps) (Amps) (Amps)
1 -2.3893 0.00000E+00 0.00000E+00 0.00000E+00
2 0.0000 -1.67168E-31 -2.33182E-22 -2.33182E-22
Electrode Flux Displacement Current Total Current
(Coul) (Amps) (Amps)
1 -4.76421E-16 0.00000E+00 0.00000E+00
2 -1.51177E-32 0.00000E+00 -2.33182E-22
Convergence criterion completely met
Total cpu time for Newton equation assembly = 0.1000
Total cpu time for Newton linear solves = 0.0667 ( 0.0667)
Total cpu time for bias point = 0.1667
Total cpu time = 5.9667
Ac analysis :
Ac voltage = 2.585100E-03
Frequency = 1.000000E+00 Hz
Electrode # 1
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 -7.38229E-27 -5.40496E-18
2 2.84076E-18 5.40496E-18 -4.83236E-28 2.53981E-28
66. Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y11 -7.38229E-27 -5.40496E-18 -2.85571E-24 -3.32763E-16
Y21 2.84076E-18 5.40496E-18 1.09890E-15 3.32763E-16
Electrode # 2
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 7.38229E-27 5.40496E-18
2 -4.69073E-18 -5.40496E-18 4.83236E-28 -4.19379E-28
Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y12 7.38229E-27 5.40496E-18 2.85571E-24 3.32763E-16
Y22 -4.69073E-18 -5.40496E-18 -1.81453E-15 -3.32763E-16
Total cpu time for Newton equation assembly = 0.0333
Total cpu time for Newton linear solves = 0.0333 ( 0.0333)
Total cpu time for ac analysis = 0.0667
Total cpu time = 6.0333
Solution for bias:
V1 = -2.3282792E+00 V2 = 0.0000000E+00
Previous solution used as initial guess
o-itr i-itr psi-error n-error p-error
1 0 7.9263E-01 R( 0)
1 1 2.3390E+00 U( 1)
68. Total cpu time for Newton linear solves = 0.0333 ( 0.0333)
Total cpu time for bias point = 0.1667
Total cpu time = 6.2000
Ac analysis :
Ac voltage = 2.585100E-03
Frequency = 1.000000E+00 Hz
Electrode # 1
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 -7.36050E-27 -5.39678E-18
2 3.23868E-18 5.39678E-18 -4.82504E-28 2.89557E-28
Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y11 -7.36050E-27 -5.39678E-18 -2.84728E-24 -3.32259E-16
Y21 3.23868E-18 5.39678E-18 1.25283E-15 3.32259E-16
Electrode # 2
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 7.36050E-27 5.39678E-18
2 2.82312E-17 -5.39678E-18 4.82504E-28 2.52403E-27
Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y12 7.36050E-27 5.39678E-18 2.84728E-24 3.32259E-16
Y22 2.82312E-17 -5.39678E-18 1.09207E-14 -3.32259E-16
69. Total cpu time for Newton equation assembly = 0.0333
Total cpu time for Newton linear solves = 0.0333 ( 0.0333)
Total cpu time for ac analysis = 0.0667
Total cpu time = 6.2667
Solution for bias:
V1 = -2.2672137E+00 V2 = 0.0000000E+00
Previous solution used as initial guess
o-itr i-itr psi-error n-error p-error
1 0 7.8886E-01 R( 0)
1 1 2.3390E+00 U( 1)
1 1 3.1900E-05 R( 1)
1 2* 1.8438E-03 U( 3)
1 2* 1.8547E-08 R( 1)
1 3* 1.1880E-06 U( 3)
1 3* 6.3882E-12 R( 1)
1 0 1.0000E+00 R( 0)
1 1 1.0331E-14 U( 1)
1 1 1.7496E-02 R( 1)
1 0 1.0000E+00 R( 0)
1 1 2.9249E-15 U( 1)
1 1 6.6895E-02 R( 1)
2 0 3.8356E-11 R( 0)
2 1 5.4899E-13 U( 1)
2 1 4.7803E-11 R( 1)
2 0 1.0000E+00 R( 0)
2 1 7.6892E-15 U( 1)
2 1 1.6927E-02 R( 1)
2 0 1.0000E+00 R( 0)
70. 2 1 1.6756E-15 U( 1)
2 1 2.5549E-01 R( 1)
1 0 2.1737E-13 1.8463E-21 3.9830E-15 R( 0)
1 1 4.0578E-15 3.8336E-15 4.0634E-15 U( 1)
1 1 1.4633E-13 1.9337E-20 6.8792E-14 R( 1)
Electrode Voltage Electron Current Hole Current Conduction Current
(Volts) (Amps) (Amps) (Amps)
1 -2.2672 0.00000E+00 0.00000E+00 0.00000E+00
2 0.0000 -1.67168E-31 -2.33182E-22 -2.33182E-22
Electrode Flux Displacement Current Total Current
(Coul) (Amps) (Amps)
1 -4.35843E-16 0.00000E+00 0.00000E+00
2 -1.51177E-32 0.00000E+00 -2.33182E-22
Convergence criterion completely met
Total cpu time for Newton equation assembly = 0.1333
Total cpu time for Newton linear solves = 0.0667 ( 0.0667)
Total cpu time for bias point = 0.2000
Total cpu time = 6.4667
Ac analysis :
Ac voltage = 2.585100E-03
Frequency = 1.000000E+00 Hz
Electrode # 1
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 -7.33693E-27 -5.38791E-18
2 3.93624E-18 5.38791E-18 -4.81711E-28 3.51924E-28
71. Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y11 -7.33693E-27 -5.38791E-18 -2.83816E-24 -3.31713E-16
Y21 3.93624E-18 5.38791E-18 1.52267E-15 3.31713E-16
Electrode # 2
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 7.33693E-27 5.38791E-18
2 1.04399E-17 -5.38791E-18 4.81711E-28 9.33390E-28
Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y12 7.33693E-27 5.38791E-18 2.83816E-24 3.31713E-16
Y22 1.04399E-17 -5.38791E-18 4.03849E-15 -3.31713E-16
Total cpu time for Newton equation assembly = -0.0000
Total cpu time for Newton linear solves = 0.0333 ( 0.0333)
Total cpu time for ac analysis = 0.0333
Total cpu time = 6.5000
Solution for bias:
V1 = -2.2061482E+00 V2 = 0.0000000E+00
Previous solution used as initial guess
o-itr i-itr psi-error n-error p-error
1 0 7.8511E-01 R( 0)
1 1 2.3390E+00 U( 1)
73. Total cpu time for Newton linear solves = 0.0333 ( 0.0333)
Total cpu time for bias point = 0.2000
Total cpu time = 6.7000
Ac analysis :
Ac voltage = 2.585100E-03
Frequency = 1.000000E+00 Hz
Electrode # 1
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 -7.31134E-27 -5.37827E-18
2 3.15604E-18 5.37827E-18 -4.80849E-28 2.82168E-28
Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y11 -7.31134E-27 -5.37827E-18 -2.82826E-24 -3.31120E-16
Y21 3.15604E-18 5.37827E-18 1.22086E-15 3.31120E-16
Electrode # 2
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 7.31134E-27 5.37827E-18
2 -7.88127E-18 -5.37827E-18 4.80849E-28 -7.04632E-28
Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y12 7.31134E-27 5.37827E-18 2.82826E-24 3.31120E-16
Y22 -7.88127E-18 -5.37827E-18 -3.04873E-15 -3.31120E-16
74. Total cpu time for Newton equation assembly = -0.0000
Total cpu time for Newton linear solves = 0.0333 ( 0.0333)
Total cpu time for ac analysis = 0.0333
Total cpu time = 6.7333
Solution for bias:
V1 = -2.1450827E+00 V2 = 0.0000000E+00
Previous solution used as initial guess
o-itr i-itr psi-error n-error p-error
1 0 7.8137E-01 R( 0)
1 1 2.3391E+00 U( 1)
1 1 3.2781E-05 R( 1)
1 2* 2.1817E-03 U( 3)
1 2* 2.2568E-08 R( 1)
1 3* 1.6547E-06 U( 3)
1 3* 6.2217E-12 R( 1)
1 0 1.0000E+00 R( 0)
1 1 1.0201E-14 U( 1)
1 1 1.8814E-02 R( 1)
1 0 1.0000E+00 R( 0)
1 1 5.2246E-15 U( 1)
1 1 6.5447E-02 R( 1)
2 0 4.1572E-11 R( 0)
2 1 1.0576E-12 U( 1)
2 1 3.7478E-11 R( 1)
2 0 1.0000E+00 R( 0)
2 1 7.0542E-15 U( 1)
2 1 1.7883E-02 R( 1)
2 0 1.0000E+00 R( 0)
75. 2 1 1.4265E-15 U( 1)
2 1 2.0902E-01 R( 1)
1 0 1.5461E-13 1.9732E-21 3.4730E-15 R( 0)
1 1 5.1318E-15 2.2256E-15 3.1893E-15 U( 1)
1 1 1.5626E-13 2.0456E-20 7.4983E-14 R( 1)
Electrode Voltage Electron Current Hole Current Conduction Current
(Volts) (Amps) (Amps) (Amps)
1 -2.1451 0.00000E+00 0.00000E+00 0.00000E+00
2 0.0000 -1.67168E-31 -2.33182E-22 -2.33182E-22
Electrode Flux Displacement Current Total Current
(Coul) (Amps) (Amps)
1 -3.95404E-16 0.00000E+00 0.00000E+00
2 -1.51177E-32 0.00000E+00 -2.33182E-22
Convergence criterion completely met
Total cpu time for Newton equation assembly = 0.1667
Total cpu time for Newton linear solves = 0.0333 ( 0.0333)
Total cpu time for bias point = 0.2000
Total cpu time = 6.9333
Ac analysis :
Ac voltage = 2.585100E-03
Frequency = 1.000000E+00 Hz
Electrode # 1
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 -7.28349E-27 -5.36776E-18
2 2.93052E-18 5.36776E-18 -4.79910E-28 2.62006E-28
76. Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y11 -7.28349E-27 -5.36776E-18 -2.81749E-24 -3.30473E-16
Y21 2.93052E-18 5.36776E-18 1.13362E-15 3.30473E-16
Electrode # 2
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 7.28349E-27 5.36776E-18
2 -2.49989E-17 -5.36776E-18 4.79910E-28 -2.23506E-27
Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y12 7.28349E-27 5.36776E-18 2.81749E-24 3.30473E-16
Y22 -2.49989E-17 -5.36776E-18 -9.67040E-15 -3.30473E-16
Total cpu time for Newton equation assembly = 0.0333
Total cpu time for Newton linear solves = -0.0000 ( -0.0000)
Total cpu time for ac analysis = 0.0333
Total cpu time = 6.9667
Solution for bias:
V1 = -2.0840171E+00 V2 = 0.0000000E+00
Previous solution used as initial guess
o-itr i-itr psi-error n-error p-error
1 0 7.7765E-01 R( 0)
1 1 2.3391E+00 U( 1)
78. Total cpu time for Newton linear solves = 0.0333 ( 0.0333)
Total cpu time for bias point = 0.2000
Total cpu time = 7.1667
Ac analysis :
Ac voltage = 2.585100E-03
Frequency = 1.000000E+00 Hz
Electrode # 1
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 -7.25307E-27 -5.35626E-18
2 1.92289E-18 5.35626E-18 -4.78882E-28 1.71918E-28
Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y11 -7.25307E-27 -5.35626E-18 -2.80572E-24 -3.29765E-16
Y21 1.92289E-18 5.35626E-18 7.43837E-16 3.29765E-16
Electrode # 2
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 7.25307E-27 5.35626E-18
2 -4.87297E-18 -5.35626E-18 4.78882E-28 -4.35672E-28
Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y12 7.25307E-27 5.35626E-18 2.80572E-24 3.29765E-16
Y22 -4.87297E-18 -5.35626E-18 -1.88502E-15 -3.29765E-16
79. Total cpu time for Newton equation assembly = 0.0333
Total cpu time for Newton linear solves = 0.0333 ( 0.0333)
Total cpu time for ac analysis = 0.0667
Total cpu time = 7.2333
Solution for bias:
V1 = -2.0229516E+00 V2 = 0.0000000E+00
Previous solution used as initial guess
o-itr i-itr psi-error n-error p-error
1 0 7.7394E-01 R( 0)
1 1 2.3392E+00 U( 1)
1 1 3.3787E-05 R( 1)
1 2* 2.6181E-03 U( 3)
1 2* 2.7992E-08 R( 1)
1 3* 2.3679E-06 U( 3)
1 3* 6.3865E-12 R( 1)
1 0 1.0000E+00 R( 0)
1 1 8.6633E-15 U( 1)
1 1 2.1355E-02 R( 1)
1 0 1.0000E+00 R( 0)
1 1 2.7441E-15 U( 1)
1 1 5.4021E-02 R( 1)
2 0 4.7969E-11 R( 0)
2 1 2.1464E-12 U( 1)
2 1 4.8250E-11 R( 1)
2 0 1.0000E+00 R( 0)
2 1 6.7912E-15 U( 1)
2 1 1.8551E-02 R( 1)
2 0 1.0000E+00 R( 0)
80. 2 1 2.5475E-15 U( 1)
2 1 1.6338E-01 R( 1)
1 0 1.7877E-13 2.0200E-21 3.2482E-15 R( 0)
1 1 5.1026E-15 2.7546E-15 2.5537E-15 U( 1)
1 1 2.0731E-13 1.9848E-20 6.0803E-14 R( 1)
Electrode Voltage Electron Current Hole Current Conduction Current
(Volts) (Amps) (Amps) (Amps)
1 -2.0230 0.00000E+00 0.00000E+00 0.00000E+00
2 0.0000 -1.67168E-31 -2.33182E-22 -2.33182E-22
Electrode Flux Displacement Current Total Current
(Coul) (Amps) (Amps)
1 -3.55131E-16 0.00000E+00 0.00000E+00
2 -1.51177E-32 0.00000E+00 -2.33182E-22
Convergence criterion completely met
Total cpu time for Newton equation assembly = 0.1000
Total cpu time for Newton linear solves = 0.0667 ( 0.0667)
Total cpu time for bias point = 0.1667
Total cpu time = 7.4000
Ac analysis :
Ac voltage = 2.585100E-03
Frequency = 1.000000E+00 Hz
Electrode # 1
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 -7.21971E-27 -5.34364E-18
2 1.98000E-18 5.34364E-18 -4.77753E-28 1.77024E-28
81. Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y11 -7.21971E-27 -5.34364E-18 -2.79282E-24 -3.28988E-16
Y21 1.98000E-18 5.34364E-18 7.65930E-16 3.28988E-16
Electrode # 2
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 7.21971E-27 5.34364E-18
2 -1.18805E-17 -5.34364E-18 4.77753E-28 -1.06219E-27
Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y12 7.21971E-27 5.34364E-18 2.79282E-24 3.28988E-16
Y22 -1.18805E-17 -5.34364E-18 -4.59576E-15 -3.28988E-16
Total cpu time for Newton equation assembly = 0.0333
Total cpu time for Newton linear solves = -0.0000 ( -0.0000)
Total cpu time for ac analysis = 0.0667
Total cpu time = 7.4667
Solution for bias:
V1 = -1.9618861E+00 V2 = 0.0000000E+00
Previous solution used as initial guess
o-itr i-itr psi-error n-error p-error
1 0 7.7025E-01 R( 0)
1 1 2.3392E+00 U( 1)
83. Total cpu time for Newton linear solves = 0.0000 ( 0.0000)
Total cpu time for bias point = 0.1667
Total cpu time = 7.6333
Ac analysis :
Ac voltage = 2.585100E-03
Frequency = 1.000000E+00 Hz
Electrode # 1
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 -7.18300E-27 -5.32971E-18
2 2.98300E-18 5.32971E-18 -4.76508E-28 2.66698E-28
Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y11 -7.18300E-27 -5.32971E-18 -2.77862E-24 -3.28130E-16
Y21 2.98300E-18 5.32971E-18 1.15392E-15 3.28130E-16
Electrode # 2
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 7.18300E-27 5.32971E-18
2 -2.13301E-17 -5.32971E-18 4.76508E-28 -1.90704E-27
Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y12 7.18300E-27 5.32971E-18 2.77862E-24 3.28130E-16
Y22 -2.13301E-17 -5.32971E-18 -8.25118E-15 -3.28130E-16
84. Total cpu time for Newton equation assembly = 0.0333
Total cpu time for Newton linear solves = 0.0333 ( 0.0333)
Total cpu time for ac analysis = 0.0667
Total cpu time = 7.7000
Solution for bias:
V1 = -1.9008206E+00 V2 = 0.0000000E+00
Previous solution used as initial guess
o-itr i-itr psi-error n-error p-error
1 0 7.6658E-01 R( 0)
1 1 2.3393E+00 U( 1)
1 1 3.4959E-05 R( 1)
1 2* 3.1940E-03 U( 3)
1 2* 3.5554E-08 R( 1)
1 3* 3.4965E-06 U( 3)
1 3* 9.8465E-12 R( 1)
1 0 1.0000E+00 R( 0)
1 1 1.0725E-14 U( 1)
1 1 1.7214E-02 R( 1)
1 0 1.0000E+00 R( 0)
1 1 4.1263E-15 U( 1)
1 1 5.8682E-02 R( 1)
2 0 8.4165E-11 R( 0)
2 1 4.6465E-12 U( 1)
2 1 7.2724E-11 R( 1)
2 0 1.0000E+00 R( 0)
2 1 8.8916E-15 U( 1)
2 1 1.6272E-02 R( 1)
2 0 1.0000E+00 R( 0)
85. 2 1 2.1521E-15 U( 1)
2 1 3.0008E-01 R( 1)
1 0 2.3904E-13 2.1267E-21 3.3729E-15 R( 0)
1 1 4.4557E-15 3.9147E-15 4.2208E-15 U( 1)
1 1 2.7628E-13 2.0933E-20 4.2687E-14 R( 1)
Electrode Voltage Electron Current Hole Current Conduction Current
(Volts) (Amps) (Amps) (Amps)
1 -1.9008 0.00000E+00 0.00000E+00 0.00000E+00
2 0.0000 -1.67168E-31 -2.33182E-22 -2.33182E-22
Electrode Flux Displacement Current Total Current
(Coul) (Amps) (Amps)
1 -3.15058E-16 0.00000E+00 0.00000E+00
2 -1.51177E-32 0.00000E+00 -2.33182E-22
Convergence criterion completely met
Total cpu time for Newton equation assembly = 0.1667
Total cpu time for Newton linear solves = -0.0000 ( -0.0000)
Total cpu time for bias point = 0.1667
Total cpu time = 7.8667
Ac analysis :
Ac voltage = 2.585100E-03
Frequency = 1.000000E+00 Hz
Electrode # 1
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 -7.14241E-27 -5.31428E-18
2 2.86320E-18 5.31428E-18 -4.75128E-28 2.55987E-28
86. Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y11 -7.14241E-27 -5.31428E-18 -2.76292E-24 -3.27180E-16
Y21 2.86320E-18 5.31428E-18 1.10758E-15 3.27180E-16
Electrode # 2
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 7.14241E-27 5.31428E-18
2 1.18206E-17 -5.31428E-18 4.75128E-28 1.05683E-27
Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y12 7.14241E-27 5.31428E-18 2.76292E-24 3.27180E-16
Y22 1.18206E-17 -5.31428E-18 4.57258E-15 -3.27180E-16
Total cpu time for Newton equation assembly = 0.0333
Total cpu time for Newton linear solves = 0.0333 ( 0.0333)
Total cpu time for ac analysis = 0.0667
Total cpu time = 7.9333
Solution for bias:
V1 = -1.8397550E+00 V2 = 0.0000000E+00
Previous solution used as initial guess
o-itr i-itr psi-error n-error p-error
1 0 7.6292E-01 R( 0)
1 1 2.3393E+00 U( 1)
88. Total cpu time for Newton linear solves = -0.0000 ( -0.0000)
Total cpu time for bias point = 0.1667
Total cpu time = 8.1000
Ac analysis :
Ac voltage = 2.585100E-03
Frequency = 1.000000E+00 Hz
Electrode # 1
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 -7.09734E-27 -5.29710E-18
2 3.42567E-18 5.29710E-18 -4.73593E-28 3.06276E-28
Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y11 -7.09734E-27 -5.29710E-18 -2.74548E-24 -3.26123E-16
Y21 3.42567E-18 5.29710E-18 1.32516E-15 3.26123E-16
Electrode # 2
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 7.09734E-27 5.29710E-18
2 4.50231E-18 -5.29710E-18 4.73593E-28 4.02532E-28
Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y12 7.09734E-27 5.29710E-18 2.74548E-24 3.26123E-16
Y22 4.50231E-18 -5.29710E-18 1.74164E-15 -3.26123E-16
89. Total cpu time for Newton equation assembly = 0.0333
Total cpu time for Newton linear solves = 0.0333 ( 0.0333)
Total cpu time for ac analysis = 0.0667
Total cpu time = 8.1667
Solution for bias:
V1 = -1.7786895E+00 V2 = 0.0000000E+00
Previous solution used as initial guess
o-itr i-itr psi-error n-error p-error
1 0 7.5929E-01 R( 0)
1 1 2.3394E+00 U( 1)
1 1 3.6365E-05 R( 1)
1 2* 3.9725E-03 U( 3)
1 2* 4.6526E-08 R( 1)
1 3* 5.3554E-06 U( 3)
1 3* 9.1051E-12 R( 1)
1 0 1.0000E+00 R( 0)
1 1 8.1790E-15 U( 1)
1 1 1.6849E-02 R( 1)
1 0 1.0000E+00 R( 0)
1 1 2.8340E-15 U( 1)
1 1 6.8327E-02 R( 1)
2 0 8.9943E-11 R( 0)
2 1 1.0797E-11 U( 1)
2 1 8.2508E-11 R( 1)
2 0 1.0000E+00 R( 0)
2 1 8.0021E-15 U( 1)
2 1 1.7423E-02 R( 1)
2 0 1.0000E+00 R( 0)
90. 2 1 1.9905E-15 U( 1)
2 1 1.6885E-01 R( 1)
1 0 2.3692E-13 2.2683E-21 2.7260E-15 R( 0)
1 1 4.6760E-15 4.0676E-15 4.4440E-15 U( 1)
1 1 2.2674E-13 2.3092E-20 4.8461E-14 R( 1)
Electrode Voltage Electron Current Hole Current Conduction Current
(Volts) (Amps) (Amps) (Amps)
1 -1.7787 0.00000E+00 0.00000E+00 0.00000E+00
2 0.0000 -1.67168E-31 -2.33182E-22 -2.33182E-22
Electrode Flux Displacement Current Total Current
(Coul) (Amps) (Amps)
1 -2.75230E-16 0.00000E+00 0.00000E+00
2 -1.51177E-32 0.00000E+00 -2.33182E-22
Convergence criterion completely met
Total cpu time for Newton equation assembly = 0.0667
Total cpu time for Newton linear solves = 0.0667 ( 0.0667)
Total cpu time for bias point = 0.1667
Total cpu time = 8.3333
Ac analysis :
Ac voltage = 2.585100E-03
Frequency = 1.000000E+00 Hz
Electrode # 1
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 -7.04703E-27 -5.27788E-18
2 2.27284E-18 5.27788E-18 -4.71874E-28 2.03206E-28
91. Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y11 -7.04703E-27 -5.27788E-18 -2.72602E-24 -3.24939E-16
Y21 2.27284E-18 5.27788E-18 8.79208E-16 3.24939E-16
Electrode # 2
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 7.04703E-27 5.27788E-18
2 2.11746E-18 -5.27788E-18 4.71874E-28 1.89313E-28
Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y12 7.04703E-27 5.27788E-18 2.72602E-24 3.24939E-16
Y22 2.11746E-18 -5.27788E-18 8.19101E-16 -3.24939E-16
Total cpu time for Newton equation assembly = 0.0333
Total cpu time for Newton linear solves = 0.0333 ( 0.0333)
Total cpu time for ac analysis = 0.0667
Total cpu time = 8.4000
Solution for bias:
V1 = -1.7176240E+00 V2 = 0.0000000E+00
Previous solution used as initial guess
o-itr i-itr psi-error n-error p-error
1 0 7.5569E-01 R( 0)
1 1 2.3395E+00 U( 1)
93. Total cpu time for Newton linear solves = 0.0333 ( 0.0333)
Total cpu time for bias point = 0.1667
Total cpu time = 8.5667
Ac analysis :
Ac voltage = 2.585100E-03
Frequency = 1.000000E+00 Hz
Electrode # 1
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 -6.99057E-27 -5.25623E-18
2 2.78499E-18 5.25623E-18 -4.69939E-28 2.48994E-28
Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y11 -6.99057E-27 -5.25623E-18 -2.70418E-24 -3.23607E-16
Y21 2.78499E-18 5.25623E-18 1.07732E-15 3.23607E-16
Electrode # 2
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 6.99057E-27 5.25623E-18
2 9.50796E-18 -5.25623E-18 4.69939E-28 8.50069E-28
Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y12 6.99057E-27 5.25623E-18 2.70418E-24 3.23607E-16
Y22 9.50796E-18 -5.25623E-18 3.67798E-15 -3.23607E-16
94. Total cpu time for Newton equation assembly = 0.0333
Total cpu time for Newton linear solves = 0.0333 ( 0.0333)
Total cpu time for ac analysis = 0.0667
Total cpu time = 8.6333
Solution for bias:
V1 = -1.6565585E+00 V2 = 0.0000000E+00
Previous solution used as initial guess
o-itr i-itr psi-error n-error p-error
1 0 7.5210E-01 R( 0)
1 1 2.3396E+00 U( 1)
1 1 3.8122E-05 R( 1)
1 2* 5.0557E-03 U( 3)
1 2* 6.3228E-08 R( 1)
1 3* 8.5630E-06 U( 3)
1 3* 2.9221E-12 R( 1)
1 0 1.0000E+00 R( 0)
1 1 8.6230E-15 U( 1)
1 1 1.5624E-02 R( 1)
1 0 1.0000E+00 R( 0)
1 1 4.6246E-15 U( 1)
1 1 9.5470E-02 R( 1)
2 0 3.4027E-11 R( 0)
2 1 2.7271E-11 U( 1)
2 1 4.9863E-11 R( 1)
2 0 1.0000E+00 R( 0)
2 1 8.5966E-15 U( 1)
2 1 1.2893E-02 R( 1)
2 0 1.0000E+00 R( 0)
95. 2 1 3.3105E-15 U( 1)
2 1 1.8310E-01 R( 1)
1 0 1.2262E-13 2.1486E-21 3.2869E-15 R( 0)
1 1 3.6646E-15 3.1514E-15 3.1197E-15 U( 1)
1 1 1.0843E-13 2.6204E-20 4.2240E-14 R( 1)
Electrode Voltage Electron Current Hole Current Conduction Current
(Volts) (Amps) (Amps) (Amps)
1 -1.6566 0.00000E+00 0.00000E+00 0.00000E+00
2 0.0000 -1.67168E-31 -1.16591E-22 -1.16591E-22
Electrode Flux Displacement Current Total Current
(Coul) (Amps) (Amps)
1 -2.35712E-16 0.00000E+00 0.00000E+00
2 -1.51177E-32 0.00000E+00 -1.16591E-22
Convergence criterion completely met
Total cpu time for Newton equation assembly = 0.1667
Total cpu time for Newton linear solves = 0.0333 ( 0.0333)
Total cpu time for bias point = 0.2000
Total cpu time = 8.8333
Ac analysis :
Ac voltage = 2.585100E-03
Frequency = 1.000000E+00 Hz
Electrode # 1
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 -6.92683E-27 -5.23171E-18
2 2.70133E-18 5.23171E-18 -4.67746E-28 2.41515E-28
96. Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y11 -6.92683E-27 -5.23171E-18 -2.67952E-24 -3.22097E-16
Y21 2.70133E-18 5.23171E-18 1.04496E-15 3.22097E-16
Electrode # 2
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 6.92683E-27 5.23171E-18
2 -3.84577E-18 -5.23171E-18 4.67746E-28 -3.43834E-28
Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y12 6.92683E-27 5.23171E-18 2.67952E-24 3.22097E-16
Y22 -3.84577E-18 -5.23171E-18 -1.48767E-15 -3.22097E-16
Total cpu time for Newton equation assembly = -0.0000
Total cpu time for Newton linear solves = 0.0333 ( 0.0333)
Total cpu time for ac analysis = 0.0333
Total cpu time = 8.8667
Solution for bias:
V1 = -1.5954929E+00 V2 = 0.0000000E+00
Previous solution used as initial guess
o-itr i-itr psi-error n-error p-error
1 0 7.4855E-01 R( 0)
1 1 2.3397E+00 U( 1)
98. Convergence criterion completely met
Total cpu time for Newton equation assembly = 0.1667
Total cpu time for Newton linear solves = 0.0333 ( 0.0333)
Total cpu time for bias point = 0.2000
Total cpu time = 9.0667
Ac analysis :
Ac voltage = 2.585100E-03
Frequency = 1.000000E+00 Hz
Electrode # 1
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 -6.85440E-27 -5.20373E-18
2 2.02515E-18 5.20373E-18 -4.65244E-28 1.81060E-28
Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y11 -6.85440E-27 -5.20373E-18 -2.65150E-24 -3.20374E-16
Y21 2.02515E-18 5.20373E-18 7.83392E-16 3.20374E-16
Electrode # 2
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 6.85440E-27 5.20373E-18
2 -5.11543E-18 -5.20373E-18 4.65244E-28 -4.57350E-28
Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
99. Y12 6.85440E-27 5.20373E-18 2.65150E-24 3.20374E-16
Y22 -5.11543E-18 -5.20373E-18 -1.97881E-15 -3.20374E-16
Total cpu time for Newton equation assembly = 0.0333
Total cpu time for Newton linear solves = 0.0333 ( 0.0333)
Total cpu time for ac analysis = 0.0667
Total cpu time = 9.1333
Solution for bias:
V1 = -1.5344274E+00 V2 = 0.0000000E+00
Previous solution used as initial guess
o-itr i-itr psi-error n-error p-error
1 0 7.4502E-01 R( 0)
1 1 2.3398E+00 U( 1)
1 1 4.0446E-05 R( 1)
1 2* 6.6134E-03 U( 3)
1 2* 9.0118E-08 R( 1)
1 3* 1.4403E-05 U( 3)
1 3* 3.9462E-12 R( 1)
1 4* 7.5927E-11 U( 4)
1 4* 5.4046E-12 R( 1)
1 0 1.0000E+00 R( 0)
1 1 9.2649E-15 U( 1)
1 1 1.5623E-02 R( 1)
1 0 1.0000E+00 R( 0)
1 1 4.5423E-15 U( 1)
1 1 8.1041E-02 R( 1)
2 0 7.6177E-11 R( 0)
2 1 3.6308E-15 U( 1)
2 1 5.1138E-11 R( 1)
100. 2 0 1.0000E+00 R( 0)
2 1 6.0739E-15 U( 1)
2 1 2.4831E-02 R( 1)
2 0 1.0000E+00 R( 0)
2 1 1.4600E-15 U( 1)
2 1 2.8574E-01 R( 1)
1 0 1.0488E-13 2.7626E-21 2.9802E-15 R( 0)
1 1 3.5092E-15 1.2510E-15 1.6735E-15 U( 1)
1 1 1.5580E-13 3.0081E-20 3.4110E-14 R( 1)
Electrode Voltage Electron Current Hole Current Conduction Current
(Volts) (Amps) (Amps) (Amps)
1 -1.5344 0.00000E+00 0.00000E+00 0.00000E+00
2 0.0000 -1.67168E-31 -1.16591E-22 -1.16591E-22
Electrode Flux Displacement Current Total Current
(Coul) (Amps) (Amps)
1 -1.96589E-16 0.00000E+00 0.00000E+00
2 -1.51177E-32 0.00000E+00 -1.16591E-22
Convergence criterion completely met
Total cpu time for Newton equation assembly = 0.1667
Total cpu time for Newton linear solves = 0.0000 ( 0.0000)
Total cpu time for bias point = 0.1667
Total cpu time = 9.3000
Ac analysis :
Ac voltage = 2.585100E-03
Frequency = 1.000000E+00 Hz
Electrode # 1
Electrode Conduction Current Displacement Current
(Amps) (Amps)
101. 1 -0.00000E+00 -0.00000E+00 -6.77153E-27 -5.17156E-18
2 2.57830E-18 5.17156E-18 -4.62369E-28 2.30515E-28
Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y11 -6.77153E-27 -5.17156E-18 -2.61945E-24 -3.18394E-16
Y21 2.57830E-18 5.17156E-18 9.97370E-16 3.18394E-16
Electrode # 2
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 6.77153E-27 5.17156E-18
2 1.82136E-18 -5.17156E-18 4.62369E-28 1.62842E-28
Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y12 6.77153E-27 5.17156E-18 2.61945E-24 3.18394E-16
Y22 1.82136E-18 -5.17156E-18 7.04562E-16 -3.18394E-16
Total cpu time for Newton equation assembly = 0.0333
Total cpu time for Newton linear solves = 0.0333 ( 0.0333)
Total cpu time for ac analysis = 0.0667
Total cpu time = 9.3667
Solution for bias:
V1 = -1.4733619E+00 V2 = 0.0000000E+00
Previous solution used as initial guess
103. (Coul) (Amps) (Amps)
1 -1.77215E-16 0.00000E+00 0.00000E+00
2 -1.51177E-32 0.00000E+00 -1.16591E-22
Convergence criterion completely met
Total cpu time for Newton equation assembly = 0.1667
Total cpu time for Newton linear solves = -0.0000 ( -0.0000)
Total cpu time for bias point = 0.1667
Total cpu time = 9.5333
Ac analysis :
Ac voltage = 2.585100E-03
Frequency = 1.000000E+00 Hz
Electrode # 1
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 -6.67599E-27 -5.13427E-18
2 2.30725E-18 5.13427E-18 -4.59035E-28 2.06282E-28
Element Total Current Conductance Capacitance
(Amps) (Siemens) (Farads)
Y11 -6.67599E-27 -5.13427E-18 -2.58249E-24 -3.16098E-16
Y21 2.30725E-18 5.13427E-18 8.92517E-16 3.16098E-16
Electrode # 2
Electrode Conduction Current Displacement Current
(Amps) (Amps)
1 -0.00000E+00 -0.00000E+00 6.67599E-27 5.13427E-18
2 -3.55482E-18 -5.13427E-18 4.59035E-28 -3.17821E-28